mxepstein.com · 2016. 4. 26. · 10.1 Sample Spaces and Probability 10.2 Independent and Dependent...

10.1 Sample Spaces and Probability

10.2 Independent and Dependent Events

10.3 Two-Way Tables and Probability

10.4 Probability of Disjoint and Overlapping Events

10.5 Permutations and Combinations

10.6 Binomial Distributions

10 Probability

Coaching (p. 552)

Jogging (p. 557)

Tree Growth (p. 568)

Horse Racing (p. 571)

Class Ring (p. 583)Class Ring (p. 583)

Horse Racing (p 571)

Jogging (p. 557)

CCoachihing ((p. 55552)2)

Tree Growth (p. 568)

SEE the Big Idea

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535

Maintaining Mathematical ProficiencyMaintaining Mathematical ProficiencyFinding a Percent

Example 1 What percent of 12 is 9?

a —

w =

p —

100 Write the percent proportion.

9 —

12 =

p —

100 Substitute 9 for a and 12 for w.

100 ⋅ 9 —

12 = 100 ⋅

p —

100 Multiplication Property of Equality.

75 = p Simplify.

So, 9 is 75% of 12.

Write and solve a proportion to answer the question.

1. What percent of 30 is 6? 2. What number is 68% of 25? 3. 34.4 is what percent of 86?

Making a Histogram

Example 2 The frequency table shows the ages of people at a gym. Display the data in a histogram.

Step 1 Draw and label the axes.

Step 2 Draw a bar to represent the frequency of each interval.

Ages of People at the Gym

Freq

uen

cy

0

2

4

6

8

10

12

14

Age10–19 20–29 30–39 40–49 50–59 60–69

There is nospace betweenthe bars of ahistogram.

Include anyinterval witha frequencyof 0. The barheight is 0.

Display the data in a histogram.

4. Movies Watched per Week

Movies 0–1 2–3 4–5

Frequency 35 11 6

5. ABSTRACT REASONING You want to purchase either a sofa or an arm chair at a furniture

store. Each item has the same retail price. The sofa is 20% off. The arm chair is 10% off,

and you have a coupon to get an additional 10% off the discounted price of the chair. Are

the items equally priced after the discounts are applied? Explain.

Age Frequency

10–19 7

20–29 12

30–39 6

40–49 4

50–59 0

60–69 3

Dynamic Solutions available at BigIdeasMath.com


536 Chapter 10 Probability

Mathematical Mathematical PracticesPracticesModeling with Mathematics

Mathematically profi cient students apply the mathematics they know to solve real-life problems.

Monitoring ProgressMonitoring ProgressIn Exercises 1 and 2, describe the event as unlikely, equally likely to happen or not happen, or likely. Explain your reasoning.

1. The oldest child in a family is a girl.

2. The two oldest children in a family with three children are girls.

3. Give an example of an event that is certain to occur.

Describing Likelihoods

Describe the likelihood of each event.

Probability of an Asteroid or a Meteoroid Hitting Earth

Name Diameter Probability of impact Flyby date

a. Meteoroid 6 in. 0.75 Any day

b. Apophis 886 ft 0 2029

c. 2000 SG344 121 ft 1 —

435 2068–2110

SOLUTIONa. On any given day, it is likely that a meteoroid of this size will enter Earth’s atmosphere.

If you have ever seen a “shooting star,” then you have seen a meteoroid.

b. A probability of 0 means this event is impossible.

c. With a probability of 1 —

435 ≈ 0.23%, this event is very unlikely. Of 435 identical asteroids,

you would expect only one of them to hit Earth.

Likelihoods and ProbabilitiesThe probability of an event is a measure of the likelihood that the event will occur.

Probability is a number from 0 to 1, including 0 and 1. The diagram relates likelihoods

(described in words) and probabilities.

Impossible CertainLikely

Equally likely tohappen or not happen

Unlikely

0 1

0 1

0.750.5

12

0.250% 100%75%50%25%

14

34

Words

Fraction

DecimalPercent

Core Core ConceptConcept



Mathematical Mathematical PracticesPracticesModeling with Mathematics

Mathematically profi cient students apply the mathematics they know to solve problems arising in everyday life. (MP4)

Monitoring ProgressMonitoring ProgressIn Exercises 1 and 2, describe the event as unlikely, equally likely to happen or not happen, or likely. Explain your reasoning.

1. The oldest child in a family is a girl.

2. The two oldest children in a family with three children are girls.

3. Give an example of an event that is certain to occur.

Describing Likelihoods

Describe the likelihood of each event.

Probability of an Asteroid or a Meteoroid Hitting Earth

Name Diameter Probability of impact Flyby date

a. Meteoroid 6 in. 0.75 Any day

b. Apophis 886 ft 0 2029

c. 2000 SG344 121 ft 1 —

435 2068–2110

SOLUTIONa. On any given day, it is likely that a meteoroid of this size will enter Earth’s atmosphere.

If you have ever seen a “shooting star,” then you have seen a meteoroid.

b. A probability of 0 means this event is impossible.

c. With a probability of 1 —

435 ≈ 0.23%, this event is very unlikely. Of 435 identical asteroids,

you would expect only one of them to hit Earth.

Likelihoods and ProbabilitiesThe probability of an event is a measure of the likelihood that the event will occur.

Probability is a number from 0 to 1, including 0 and 1. The diagram relates likelihoods

(described in words) and probabilities.



Unlikely

0 1

0 1

0.750.5

12

0.250% 100%75%50%25%

14

34

Words

Fraction

DecimalPercent

Core Core ConceptConcept

Section 10.1 Sample Spaces and Probability 537

Sample Spaces and Probability10.1

Essential QuestionEssential Question How can you list the possible outcomes in

the sample space of an experiment?

The sample space of an experiment is the set of all possible outcomes for

that experiment.

Finding the Sample Space of an Experiment

Work with a partner. In an experiment,

three coins are fl ipped. List the possible

outcomes in the sample space of

the experiment.


Work with a partner. List the possible outcomes in the sample space of

the experiment.

a. One six-sided die is rolled. b. Two six-sided dice are rolled.


Work with a partner. In an experiment,

a spinner is spun.

a. How many ways can you spin a 1? 2? 3? 4? 5?

b. List the sample space.

c. What is the total number of outcomes?


Work with a partner. In an experiment, a bag

contains 2 blue marbles and 5 red marbles. Two

marbles are drawn from the bag.

a. How many ways can you choose two blue? a red

then blue? a blue then red? two red?

b. List the sample space.

c. What is the total number of outcomes?

Communicate Your AnswerCommunicate Your Answer 5. How can you list the possible outcomes in the sample space of an experiment?

6. For Exploration 3, fi nd the ratio of the number of each possible outcome to

the total number of outcomes. Then fi nd the sum of these ratios. Repeat for

Exploration 4. What do you observe?

LOOKING FOR A PATTERN

To be profi cient in math, you need to look closely to discern a pattern or structure.

1 4

55

3

243

53

25

11 2

34

5

2

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10.1 Lesson What You Will LearnWhat You Will Learn Find sample spaces.

Find theoretical probabilities.

Find experimental probabilities.

Sample SpacesA probability experiment is an action, or trial, that has varying results. The possible

results of a probability experiment are outcomes. For instance, when you roll a

six-sided die, there are 6 possible outcomes: 1, 2, 3, 4, 5, or 6. A collection of one

or more outcomes is an event, such as rolling an odd number. The set of all possible

outcomes is called a sample space.

Finding a Sample Space

You fl ip a coin and roll a six-sided die. How many possible outcomes are in the

sample space? List the possible outcomes.

SOLUTION

Use a tree diagram to fi nd the outcomes in the sample space.

Coin flip

Die roll

Heads Tails

4 5 631 2 4 5 631 2

The sample space has 12 possible outcomes. They are listed below.

Heads, 1 Heads, 2 Heads, 3 Heads, 4 Heads, 5 Heads, 6

Tails, 1 Tails, 2 Tails, 3 Tails, 4 Tails, 5 Tails, 6

Monitoring ProgressMonitoring Progress Help in English and Spanish at BigIdeasMath.com

Find the number of possible outcomes in the sample space. Then list the possible outcomes.

1. You fl ip two coins. 2. You fl ip two coins and roll a six-sided die.

Theoretical ProbabilitiesThe probability of an event is a measure of the likelihood, or chance, that the

event will occur. Probability is a number from 0 to 1, including 0 and 1, and can be

expressed as a decimal, fraction, or percent.



Unlikely

0 1

0 1

0.750.5

12

0.250% 100%75%50%25%

14

34

ANOTHER WAYUsing H for “heads” and T for “tails,” you can list the outcomes as shown below.

H1 H2 H3 H4 H5 H6T1 T2 T3 T4 T5 T6

probability experiment, p. 538outcome, p. 538event, p. 538sample space, p. 538probability of an event, p. 538theoretical probability, p. 539geometric probability, p. 540experimental probability, p. 541

Previoustree diagram

Core VocabularyCore Vocabullarry



The outcomes for a specifi ed event are called favorable outcomes. When all

outcomes are equally likely, the theoretical probability of the event can be found

using the following.

Theoretical probability = Number of favorable outcomes ———

Total number of outcomes

The probability of event A is written as P(A).

Finding a Theoretical Probability

A student taking a quiz randomly guesses the answers to four true-false questions.

What is the probability of the student guessing exactly two correct answers?

SOLUTION

Step 1 Find the outcomes in the sample space. Let C represent a correct answer

and I represent an incorrect answer. The possible outcomes are:

Number correct Outcome

0 IIII

1 CIII ICII IICI IIIC

2 IICC ICIC ICCI CIIC CICI CCII

3 ICCC CICC CCIC CCCI

4 CCCC

Step 2 Identify the number of favorable outcomes and the total number of outcomes.

There are 6 favorable outcomes with exactly two correct answers and the total

number of outcomes is 16.

Step 3 Find the probability of the student guessing exactly two correct answers.

Because the student is randomly guessing, the outcomes should be equally

likely. So, use the theoretical probability formula.

P(exactly two correct answers) = Number of favorable outcomes

——— Total number of outcomes

= 6 —

16

= 3 —

8

The probability of the student guessing exactly two correct answers is 3 —

8 ,

or 37.5%.

The sum of the probabilities of all outcomes in a sample space is 1. So, when you

know the probability of event A, you can fi nd the probability of the complement of

event A. The complement of event A consists of all outcomes that are not in A and is

denoted by — A . The notation — A is read as “A bar.” You can use the following formula

to fi nd P( — A ).

ATTENDING TO PRECISION

Notice that the question uses the phrase “exactly two answers.” This phrase is more precise than saying “two answers,” which may be interpreted as “at least two” or as “exactly two.”

exactly two correct

Core Core ConceptConceptProbability of the Complement of an EventThe probability of the complement of event A is

P( — A ) = 1 − P(A).



Finding Probabilities of Complements

When two six-sided dice are rolled, there

are 36 possible outcomes, as shown. Find

the probability of each event.

a. The sum is not 6.

b. The sum is less than or equal to 9.

SOLUTION

a. P(sum is not 6) = 1 − P(sum is 6) = 1 − 5 —

36 =

31 —

36 ≈ 0.861

b. P(sum ≤ 9) = 1 − P(sum > 9) = 1 − 6 —

36 =

30 —

36 =

5 —

6 ≈ 0.833

Some probabilities are found by calculating a ratio of two lengths, areas,

or volumes. Such probabilities are called geometric probabilities.

Using Area to Find Probability

You throw a dart at the board shown. Your dart is equally likely to hit any point

inside the square board. Are you more likely to get 10 points or 0 points?

SOLUTION

The probability of getting 10 points is

P(10 points) = Area of smallest circle

—— Area of entire board

= π ⋅ 32

— 182

= 9π — 324

= π — 36

≈ 0.0873.

The probability of getting 0 points is

P(0 points) = Area outside largest circle

——— Area of entire board

= 182 − (π ⋅ 92)

—— 182

= 324 − 81π —

324

= 4 − π —

4

≈ 0.215.

You are more likely to get 0 points.


3. You fl ip a coin and roll a six-sided die. What is the probability that the coin

shows tails and the die shows 4?

Find P( — A ).

4. P(A) = 0.45 5. P(A) = 1 —

4

6. P(A) = 1 7. P(A) = 0.03

8. In Example 4, are you more likely to get 10 points or 5 points?

9. In Example 4, are you more likely to score points (10, 5, or 2) or get 0 points?

105

20

3 in.



Experimental ProbabilitiesAn experimental probability is based on repeated trials of a probability experiment.

The number of trials is the number of times the probability experiment is performed.

Each trial in which a favorable outcome occurs is called a success. The experimental

probability can be found using the following.

Experimental probability = Number of successes ——

Number of trials

Finding an Experimental Probability

Each section of the spinner shown has the same area. The

spinner was spun 20 times. The table shows the results. For

which color is the experimental probability of stopping on

the color the same as the theoretical probability?

SOLUTION

The theoretical probability of stopping on each of the four colors is l —

4 .

Use the outcomes in the table to fi nd the experimental probabilities.

P(red) = 5 —

20 =

1 —

4 P(green) =

9 —

20

P(blue) = 3 —

20 P(yellow) =

3 —

20

The experimental probability of stopping on red is the same as the

theoretical probability.

Solving a Real-Life Problem

In the United States, a survey of

2184 adults ages 18 and over found that

1328 of them have at least one pet. The

types of pets these adults have are shown

in the fi gure. What is the probability that a

pet-owning adult chosen at random

has a dog?

SOLUTION

The number of trials is the number of

pet-owning adults, 1328. A success is

a pet-owning adult who has a dog. From

the graph, there are 916 adults who said

that they have a dog.

P(pet-owning adult has a dog) = 916

— 1328

= 229

— 332

≈ 0.690

The probability that a pet-owning adult chosen at random has a dog is about 69%.


10. In Example 5, for which color is the experimental probability of stopping on

the color greater than the theoretical probability?

11. In Example 6, what is the probability that a pet-owning adult chosen at random

owns a fi sh?

Spinner Results

red green blue yellow

5 9 3 3

U.S. Adults with PetsN

um

ber

of

adu

lts

916

677

0

200

400

600

800

1000

Cat FishDog

93

Bird

146



Exercises10.1 Dynamic Solutions available at BigIdeasMath.com

1. COMPLETE THE SENTENCE A number that describes the likelihood of an event is the __________ of

the event.

2. WRITING Describe the difference between theoretical probability and experimental probability.

Vocabulary and Core Concept CheckVocabulary and Core Concept Check

In Exercises 3–6, fi nd the number of possible outcomes in the sample space. Then list the possible outcomes. (See Example 1.)

3. You roll a die and fl ip three coins.

4. You fl ip a coin and draw a marble at random

from a bag containing two purple marbles and

one white marble.

5. A bag contains four red cards numbered 1 through

4, four white cards numbered 1 through 4, and four

black cards numbered 1 through 4. You choose a card

at random.

6. You draw two marbles without replacement from

a bag containing three green marbles and four black

marbles.

7. PROBLEM SOLVING A game show airs on television

fi ve days per week. Each day, a prize is randomly

placed behind one of two doors. The contestant wins

the prize by selecting the correct door. What is the

probability that exactly two of the fi ve contestants

win a prize during a week? (See Example 2.)

8. PROBLEM SOLVING Your friend has two standard

decks of 52 playing cards and asks you to randomly

draw one card from each deck. What is the probability

that you will draw two spades?

9. PROBLEM SOLVING When two six-sided dice are

rolled, there are 36 possible outcomes. Find the

probability that (a) the sum is not 4 and (b) the sum

is greater than 5. (See Example 3.)

10. PROBLEM SOLVING The age distribution of a

population is shown. Find the probability of

each event.

65+: 13%

55–64: 12%

45–54: 15%35–44: 13%

25–34: 13%

15–24: 14%

5–14: 13%

Age Distribution

Under 5: 7%

a. A person chosen at random is at least 15 years old.

b. A person chosen at random is from 25 to

44 years old.

11. ERROR ANALYSIS A student randomly guesses the

answers to two true-false questions. Describe and

correct the error in fi nding the probability of the

student guessing both answers correctly.

The student can either guess two

incorrect answers, two correct answers,

or one of each. So the probability of

guessing both answers correctly is 1 — 3

.

✗

12. ERROR ANALYSIS A student randomly draws a

number between 1 and 30. Describe and correct the

error in fi nding the probability that the number drawn

is greater than 4.

The probability that the number is less

than 4 is 3 —

30 , or 1

— 10

. So, the probability that

the number is greater than 4 is 1 − 1 —

10 ,

or 9 —

10 .

✗

Monitoring Progress and Modeling with MathematicsMonitoring Progress and Modeling with Mathematics



13. MATHEMATICAL CONNECTIONS You throw a dart at the

board shown. Your dart is

equally likely to hit any

point inside the square

board. What is the

probability your dart

lands in the yellow

region? (See Example 4.)

14. MATHEMATICAL CONNECTIONS The map shows

the length (in miles) of shoreline along the Gulf of

Mexico for each state that borders the body of water.

What is the probability that a ship coming ashore at a

random point in the Gulf of Mexico lands in the

given state?

Gulf of Mexico

TX LAMS AL

FL367 mi

53 mi

770 mi

44 mi397 mi

a. Texas b. Alabama

c. Florida d. Louisiana

15. DRAWING CONCLUSIONS You roll a six-sided die

60 times. The table shows the results. For which

number is the experimental probability of rolling

the number the same as the theoretical probability? (See Example 5.)

Six-sided Die Results

11 14 7 10 6 12

16. DRAWING CONCLUSIONS A bag contains 5 marbles

that are each a different color. A marble is drawn,

its color is recorded, and then the marble is placed

back in the bag. This process is repeated until 30

marbles have been drawn. The table shows the results.

For which marble is the experimental probability

of drawing the marble the same as the theoretical

probability?

Drawing Results

white black red green blue

5 6 8 2 9

17. REASONING Refer to the spinner shown. The spinner

is divided into sections with the same area.

a. What is the theoretical

probability that the spinner

stops on a multiple of 3?

b. You spin the spinner 30 times.

It stops on a multiple of

3 twenty times. What is the

experimental probability of

stopping on a multiple of 3?

c. Explain why the probability you found in

part (b) is different than the probability you

found in part (a).

18. OPEN-ENDED Describe a real-life event that has a

probability of 0. Then describe a real-life event that

has a probability of 1.

19. DRAWING CONCLUSIONS A survey of 2237 adults

ages 18 and over asked which sport is their favorite.

The results are shown in the fi gure. What is the

probability that an adult chosen at random prefers

auto racing? (See Example 6.)

Favorite SportN

um

ber

of

adu

lts

Sport

805

291

0

200

400

600

800

Baseb

all

College F

ootball

Pro Fo

otball

671

Other

291

Auto R

acin

g

179

20. DRAWING CONCLUSIONS A survey of 2392 adults

ages 18 and over asked what type of food they would

be most likely to choose at a restaurant. The results

are shown in the fi gure. What is the probability that an

adult chosen at random prefers Italian food?

Survey Results

239

167

383

407

526

670

American

Italian

Mexican

Chinese

Japanese

Other

18 in.

18 in.

6 in.

4

15

30

18

924

6

12

27

21



21. ANALYZING RELATIONSHIPS Refer to the board in

Exercise 13. Order the likelihoods that the dart lands

in the given region from least likely to most likely.

A. green B. not blue

C. red D. not yellow

22. ANALYZING RELATIONSHIPS Refer to the chart

below. Order the following events from least likely

to most likely.

Friday

Chance of Rain

5%

Saturday

30%Chance of Rain

Sunday

80%Chance of Rain

Monday

90%Chance of Rain

Four - Day Forecast

A. It rains on Sunday.

B. It does not rain on Saturday.

C. It rains on Monday.

D. It does not rain on Friday.

23. USING TOOLS Use the fi gure in Example 3 to answer

each question.

a. List the possible sums that result from rolling two

six-sided dice.

b. Find the theoretical probability of rolling each sum.

c. The table below shows a simulation of rolling

two six-sided dice three times. Use a random

number generator to simulate rolling two

six-sided dice 50 times. Compare the experimental

probabilities of rolling each sum with the

theoretical probabilities.

A B

321

45

First Die Second Die Sum

3 51 6

C

84 6 10

7

24. MAKING AN ARGUMENT You fl ip a coin three times.

It lands on heads twice and on tails once. Your friend

concludes that the theoretical probability of the coin

landing heads up is P(heads up) = 2 —

3 . Is your friend

correct? Explain your reasoning.

25. MATHEMATICAL CONNECTIONS A sphere fi ts inside a cube so that it

touches each side, as shown. What

is the probability a point chosen at

random inside the cube is also inside

the sphere?

26. HOW DO YOU SEE IT? Consider the graph of f shown.

What is the probability that the

graph of y = f (x) + c intersects

the x-axis when c is a randomly

chosen integer from 1 to 6?

Explain.

27. DRAWING CONCLUSIONS A manufacturer tests

1200 computers and fi nds that 9 of them have defects.

Find the probability that a computer chosen at random

has a defect. Predict the number of computers with

defects in a shipment of 15,000 computers. Explain

your reasoning.

28. THOUGHT PROVOKING The tree diagram shows a

sample space. Write a probability problem that can

be represented by the sample space. Then write the

answer(s) to the problem.

Box A Box B Outcomes Sum Product

3

11 (1, 1)

(1, 2)

(2, 1)

(2, 2)

(3, 1)

(3, 2)

2

2

1

2

1

2

2

3

3

4

4

5

1

2

2

4

3

6

Maintaining Mathematical ProficiencyMaintaining Mathematical ProficiencyFind the product or quotient. (Section 7.3)

29. 3x — y ⋅

2x3

— y2

30. 4x9y — 3x3

⋅ 2xy

— 8y2

31. x + 3 —

x4 − 2 ⋅ (x2 − 7x + 6)

32. 2y — 5x

÷ y —

6x 33.

3x — 12x − 11

÷ x + 1

— 5x

34. 3x2 + 2x − 13 ——

x4 ÷ (x2 + 9)

Reviewing what you learned in previous grades and lessons

xf

y

−4

−2

2

(2, −4)


Section 10.2 Independent and Dependent Events 545

Independent and Dependent Events10.2

Essential QuestionEssential Question How can you determine whether two

events are independent or dependent?

Two events are independent events when the occurrence of one event does not

affect the occurrence of the other event. Two events are dependent events when

the occurrence of one event does affect the occurrence of the other event.

Identifying Independent and Dependent Events

Work with a partner. Determine whether the events are independent or dependent.

Explain your reasoning.

a. Two six-sided dice are rolled.

b. Six pieces of paper, numbered 1 through 6,

are in a bag. Two pieces of paper are selected

one at a time without replacement.

Finding Experimental Probabilities

Work with a partner.

a. In Exploration 1(a), experimentally estimate the probability that the sum of the

two numbers rolled is 7. Describe your experiment.

b. In Exploration 1(b), experimentally estimate the probability that the sum of the

two numbers selected is 7. Describe your experiment.

Finding Theoretical Probabilities


a. In Exploration 1(a), fi nd the theoretical probability that the sum of the two numbers

rolled is 7. Then compare your answer with the experimental probability you found

in Exploration 2(a).

b. In Exploration 1(b), fi nd the theoretical probability that the sum of the two numbers

selected is 7. Then compare your answer with the experimental probability you

found in Exploration 2(b).

c. Compare the probabilities you obtained in parts (a) and (b).

Communicate Your AnswerCommunicate Your Answer 4. How can you determine whether two events are independent or dependent?

5. Determine whether the events are independent or dependent. Explain your

reasoning.

a. You roll a 4 on a six-sided die and spin red on a spinner.

b. Your teacher chooses a student to lead a group, chooses another student to lead

a second group, and chooses a third student to lead a third group.

REASONING ABSTRACTLYTo be profi cient in math, you need to make sense of quantities and their relationships in problem situations.



10.2 Lesson What You Will LearnWhat You Will Learn Determine whether events are independent events.

Find probabilities of independent and dependent events.

Find conditional probabilities.

Determining Whether Events Are IndependentTwo events are independent events when the occurrence of one event does not affect

the occurrence of the other event.

Determining Whether Events Are Independent

A student taking a quiz randomly guesses the answers to four true-false questions.

Use a sample space to determine whether guessing Question 1 correctly and guessing

Question 2 correctly are independent events.

SOLUTION

Using the sample space in Example 2 on page 539:

P(correct on Question 1) = 8 —

16 =

1 —

2 P(correct on Question 2) =

8 —

16 =

1 —

2

P(correct on Question 1 and correct on Question 2) = 4 —

16 =

1 —

4

Because 1 —

2 ⋅

1 —

2 =

1 —

4 , the events are independent.

Determining Whether Events Are Independent

A group of four students includes one boy and three girls. The teacher randomly

selects one of the students to be the speaker and a different student to be the recorder.

Use a sample space to determine whether randomly selecting a girl fi rst and randomly

selecting a girl second are independent events.

SOLUTION

Let B represent the boy. Let G1, G2, and G3 represent the three girls. Use a table to list

the outcomes in the sample space.

Using the sample space:

P(girl fi rst) = 9 —

12 =

3 —

4 P(girl second) =

9 —

12 =

3 —

4

P(girl fi rst and girl second) = 6 —

12 =

1 —

2

Because 3 —

4 ⋅

3 —

4 ≠

1 —

2 , the events are not independent.

Number of girls

Outcome

1 G1B BG1

1 G2B BG2

1 G3B BG3

2 G1G2 G2G1

2 G1G3 G3G1

2 G2G3 G3G2

independent events, p. 546dependent events, p. 547conditional probability, p. 547

Previousprobabilitysample space


Core Core ConceptConceptProbability of Independent EventsWords Two events A and B are independent events if and only if the probability

that both events occur is the product of the probabilities of the events.

Symbols P(A and B) = P(A) ⋅ P(B)




1. In Example 1, determine whether guessing Question 1 incorrectly and guessing

Question 2 correctly are independent events.

2. In Example 2, determine whether randomly selecting a girl fi rst and randomly

selecting a boy second are independent events.

Finding Probabilities of EventsIn Example 1, it makes sense that the events are independent because the second guess

should not be affected by the fi rst guess. In Example 2, however, the selection of the

second person depends on the selection of the fi rst person because the same person

cannot be selected twice. These events are dependent. Two events are dependent events when the occurrence of one event does affect the occurrence of the other event.

The probability that event B occurs given that event A has occurred is called the

conditional probability of B given A and is written as P(B � A).

Finding the Probability of Independent Events

As part of a board game, you need to spin the spinner, which is divided into equal

parts. Find the probability that you get a 5 on your fi rst spin and a number greater

than 3 on your second spin.

SOLUTION

Let event A be “5 on fi rst spin” and let event B be “greater than 3 on second spin.”

The events are independent because the outcome of your second spin is not affected

by the outcome of your fi rst spin. Find the probability of each event and then multiply

the probabilities.

P(A) = 1 —

8 1 of the 8 sections is a “5.”

P(B) = 5 —

8 5 of the 8 sections (4, 5, 6, 7, 8) are greater than 3.

P(A and B) = P(A) ⋅ P(B) = 1 —

8 ⋅

5 —

8 =

5 —

64 ≈ 0.078

So, the probability that you get a 5 on your fi rst spin and a number greater than 3

on your second spin is about 7.8%.

Core Core ConceptConceptProbability of Dependent EventsWords If two events A and B are dependent events, then the probability that

both events occur is the product of the probability of the fi rst event and

the conditional probability of the second event given the fi rst event.

Symbols P(A and B) = P(A) ⋅ P(B � A)

Example Using the information in Example 2:

P(girl fi rst and girl second) = P(girl fi rst) ⋅ P(girl second � girl fi rst)

= 9 —

12 ⋅

6 —

9 =

1 —

2

MAKING SENSE OF PROBLEMS

One way that you can fi nd P(girl second � girl fi rst) is to list the 9 outcomes in which a girl is chosen fi rst and then fi nd the fraction of these outcomes in which a girl is chosen second:

G1B G2B G3B

G1G2 G2G1 G3G1

G1G3 G2G3 G3G2

21876 5 4

3233333333333333



Finding the Probability of Dependent Events

A bag contains twenty $1 bills and fi ve $100 bills. You randomly draw a bill from

the bag, set it aside, and then randomly draw another bill from the bag. Find the

probability that both events A and B will occur.

Event A: The fi rst bill is $100. Event B: The second bill is $100.

SOLUTION

The events are dependent because there is one less bill in the bag on your second draw

than on your fi rst draw. Find P(A) and P(B � A). Then multiply the probabilities.

P(A) = 5 —

25 5 of the 25 bills are $100 bills.

P(B � A) = 4 —

24 4 of the remaining 24 bills are $100 bills.

P(A and B) = P(A) ⋅ P(B � A) = 5 —

25 ⋅

4 —

24 =

1 —

5 ⋅

1 —

6 =

1 —

30 ≈ 0.033.

So, the probability that you draw two $100 bills is about 3.3%.

Comparing Independent and Dependent Events

You randomly select 3 cards from a standard deck of 52 playing cards. What is the

probability that all 3 cards are hearts when (a) you replace each card before selecting

the next card, and (b) you do not replace each card before selecting the next card?

Compare the probabilities.

SOLUTION

Let event A be “fi rst card is a heart,” event B be “second card is a heart,” and event C

be “third card is a heart.”

a. Because you replace each card before you select the next card, the events are

independent. So, the probability is

P(A and B and C) = P(A) ⋅ P(B) ⋅ P(C) = 13

— 52

⋅ 13

— 52

⋅ 13

— 52

= 1 —

64 ≈ 0.016.

b. Because you do not replace each card before you select the next card, the events are

dependent. So, the probability is

P(A and B and C ) = P(A) ⋅ P(B � A) ⋅ P(C � A and B)

= 13

— 52

⋅ 12

— 51

⋅ 11

— 50

= 11

— 850

≈ 0.013.

So, you are 1 —

64 ÷

11 —

850 ≈ 1.2 times more likely to select 3 hearts when you replace

each card before you select the next card.


3. In Example 3, what is the probability that you spin an even number and then an

odd number?

4. In Example 4, what is the probability that both bills are $1 bills?

5. In Example 5, what is the probability that none of the cards drawn are hearts

when (a) you replace each card, and (b) you do not replace each card? Compare

the probabilities.

STUDY TIPThe formulas for fi nding probabilities of independent and dependent events can be extended to three or more events.

A

t

p

S

T

t



Finding Conditional Probabilities

Using a Table to Find Conditional Probabilities

A quality-control inspector checks for defective parts. The table shows the results of

the inspector’s work. Find (a) the probability that a defective part “passes,” and

(b) the probability that a non-defective part “fails.”

SOLUTION

a. P(pass � defective) = Number of defective parts “passed”

——— Total number of defective parts

= 3 —

3 + 36 =

3 —

39 =

1 —

13 ≈ 0.077, or about 7.7%

b. P(fail � non-defective) = Number of non-defective parts “failed”

———— Total number of non-defective parts

= 11 —

450 + 11 =

11 —

461 ≈ 0.024, or about 2.4%

You can rewrite the formula for the probability of dependent events to write a rule for

fi nding conditional probabilities.

P(A) ⋅ P(B � A) = P(A and B) Write formula.

P(B � A) = P(A and B)

— P(A)

Divide each side by P(A).

Finding a Conditional Probability

At a school, 60% of students buy a school lunch. Only 10% of students buy lunch and

dessert. What is the probability that a student who buys lunch also buys dessert?

SOLUTION

Let event A be “buys lunch” and let event B be “buys dessert.” You are given

P(A) = 0.6 and P(A and B) = 0.1. Use the formula to fi nd P(B � A).

P(B � A) = P(A and B)

— P(A)

Write formula for conditional probability.

= 0.1

— 0.6

Substitute 0.1 for P(A and B) and 0.6 for P(A).

= 1 —

6 ≈ 0.167 Simplify.

So, the probability that a student who buys lunch also buys dessert is

about 16.7%.


6. In Example 6, fi nd (a) the probability that a non-defective part “passes,” and

(b) the probability that a defective part “fails.”

7. At a coffee shop, 80% of customers order coffee. Only 15% of customers order

coffee and a bagel. What is the probability that a customer who orders coffee also

orders a bagel?

STUDY TIPNote that when A and B are independent, this rule still applies because P(B) = P(B � A).

Pass Fail

Defective 3 36

Non-defective 450 11




1. WRITING Explain the difference between dependent events and independent events, and give an

example of each.

2. COMPLETE THE SENTENCE The probability that event B will occur given that event A has occurred is

called the __________ of B given A and is written as _________.


In Exercises 3–6, tell whether the events are independent or dependent. Explain your reasoning.

3. A box of granola bars contains an assortment of

fl avors. You randomly choose a granola bar and eat it.

Then you randomly choose another bar.

Event A: You choose a coconut almond bar fi rst.

Event B: You choose a cranberry almond bar second.

4. You roll a six-sided die and fl ip a coin.

Event A: You get a 4 when rolling the die.

Event B: You get tails

when fl ipping

the coin.

5. Your MP3 player contains hip-hop and rock songs.

You randomly choose a song. Then you randomly

choose another song without repeating song choices.

Event A: You choose a hip-hop song fi rst.

Event B: You choose a rock song second.

6. There are 22 novels of various genres on a shelf. You

randomly choose a novel and put it back. Then you

randomly choose another novel.

Event A: You choose a mystery novel.

Event B: You choose a science fi ction novel.

In Exercises 7–10, determine whether the events are independent. (See Examples 1 and 2.)

7. You play a game that involves

spinning a wheel. Each section

of the wheel shown has the

same area. Use a sample space

to determine whether randomly

spinning blue and then green are

independent events.

8. You have one red apple and three green apples in a

bowl. You randomly select one apple to eat now and

another apple for your lunch. Use a sample space to

determine whether randomly selecting a green apple

fi rst and randomly selecting a green apple second are

independent events.

9. A student is taking a multiple-choice test where

each question has four choices. The student randomly

guesses the answers to the fi ve-question test. Use a

sample space to determine whether guessing

Question 1 correctly and Question 2 correctly are

independent events.

10. A vase contains four white roses and one red rose.

You randomly select two roses to take home. Use

a sample space to determine whether randomly

selecting a white rose fi rst and randomly selecting a

white rose second are independent events.

11. PROBLEM SOLVING You

play a game that involves

spinning the money

wheel shown. You spin

the wheel twice. Find

the probability that you

get more than $500 on

your fi rst spin and then go

bankrupt on your second spin. (See Example 3.)




12. PROBLEM SOLVING You play a game that involves

drawing two numbers from a hat. There are 25 pieces

of paper numbered from 1 to 25 in the hat. Each

number is replaced after it is drawn. Find the

probability that you will draw the 3 on your fi rst draw

and a number greater than 10 on your second draw.

13. PROBLEM SOLVING A drawer contains 12 white

socks and 8 black socks. You randomly choose 1 sock

and do not replace it. Then you randomly choose

another sock. Find the probability that both events A

and B will occur. (See Example 4.)

Event A: The fi rst sock is white.

Event B: The second sock is white.

14. PROBLEM SOLVING A word game has 100 tiles,

98 of which are letters and 2 of which are blank.

The numbers of tiles of each letter are shown.

You randomly draw 1 tile, set it aside, and then

randomly draw another tile. Find the probability

that both events A and B will occur.

Event A:The fi rst tile

is a consonant.

Event B:The second tile

is a vowel.

15. ERROR ANALYSIS Events A and B are independent.

Describe and correct the error in fi nding P(A and B).

P(A) = 0.6 P(B) = 0.2P(A and B) = 0.6 + 0.2 = 0.8✗

16. ERROR ANALYSIS A shelf contains 3 fashion

magazines and 4 health magazines. You randomly

choose one to read, set it aside, and randomly choose

another for your friend to read. Describe and correct

the error in fi nding the probability that both events A

and B occur.

Event A: The fi rst magazine is fashion.

Event B: The second magazine is health.

P(A) = 3 — 7 P(B � A) = 4 — 7

P(A and B) = 3 — 7 ⋅ 4 — 7 = 12 — 49 ≈ 0.245

✗

17. NUMBER SENSE Events A and B are independent.

Suppose P(B) = 0.4 and P(A and B) = 0.13. Find P(A).

18. NUMBER SENSE Events A and B are dependent.

Suppose P(B � A) = 0.6 and P(A and B) = 0.15.

Find P(A).

19. ANALYZING RELATIONSHIPS You randomly select

three cards from a standard deck of 52 playing

cards. What is the probability that all three cards are

face cards when (a) you replace each card before

selecting the next card, and (b) you do not replace

each card before selecting the next card? Compare the

probabilities. (See Example 5.)

20. ANALYZING RELATIONSHIPS A bag contains 9 red

marbles, 4 blue marbles, and 7 yellow marbles. You

randomly select three marbles from the bag. What

is the probability that all three marbles are red when

(a) you replace each marble before selecting the next

marble, and (b) you do not replace each marble before

selecting the next marble? Compare the probabilities.

21. ATTEND TO PRECISION The table shows the number

of species in the United States listed as endangered

and threatened. Find (a) the probability that a

randomly selected endangered species is a bird, and

(b) the probability that a randomly selected mammal

is endangered. (See Example 6.)

Endangered Threatened

Mammals 70 16

Birds 80 16

Other 318 142

22. ATTEND TO PRECISION The table shows the number

of tropical cyclones that formed during the hurricane

seasons over a 12-year period. Find (a) the probability

to predict whether a future tropical cyclone in the

Northern Hemisphere is a hurricane, and (b) the

probability to predict whether a hurricane is in the

Southern Hemisphere.

Type of Tropical Cyclone

Northern Hemisphere

Southern Hemisphere

tropical depression 100 107

tropical storm 342 487

hurricane 379 525

23. PROBLEM SOLVING At a school, 43% of students

attend the homecoming football game. Only 23%

of students go to the game and the homecoming

dance. What is the probability that a student who

attends the football game also attends the dance? (See Example 7.)

− 9

− 2

− 2

− 4

− 12

− 2

− 3

− 2

− 9

− 1

− 1

− 4

− 2

− 6

− 2

− 2

− 1

− 2

− 1

− 2

Blank

− 8

− 2

− 1

− 6

− 4

− 6

− 4



24. PROBLEM SOLVING At a gas station, 84% of

customers buy gasoline. Only 5% of customers buy

gasoline and a beverage. What is the probability that a

customer who buys gasoline also buys a beverage?

25. PROBLEM SOLVING You and 19 other students

volunteer to present the “Best Teacher” award at a

school banquet. One student volunteer will be chosen

to present the award. Each student worked at least

1 hour in preparation for the banquet. You worked

for 4 hours, and the group worked a combined total

of 45 hours. For each situation, describe a process

that gives you a “fair” chance to be chosen, and fi nd

the probability that you are chosen.

a. “Fair” means equally likely.

b. “Fair” means proportional to the number of hours

each student worked in preparation.

26. HOW DO YOU SEE IT? A bag contains one red marble

and one blue marble. The diagrams show the possible

outcomes of randomly choosing two marbles using

different methods. For each method, determine

whether the marbles were selected with or

without replacement.

a. 2ndDraw

1stDraw

b. 2ndDraw

1stDraw

27. MAKING AN ARGUMENT A meteorologist claims

that there is a 70% chance of rain. When it rains,

there is a 75% chance that your softball game will be

rescheduled. Your friend believes the game is more

likely to be rescheduled than played. Is your friend

correct? Explain your reasoning.

28. THOUGHT PROVOKING Two six-sided dice are rolled

once. Events A and B are represented by the diagram.

Describe each event. Are the two events dependent or

independent? Justify your reasoning.

4

5

6

3

2

4 5 631 2

1B

A

29. MODELING WITH MATHEMATICS A football team is

losing by 14 points near the end of a game. The team

scores two touchdowns (worth 6 points each) before

the end of the game. After each touchdown, the coach

must decide whether to go for 1 point with a kick

(which is successful 99% of the time) or 2 points with

a run or pass (which is successful 45% of the time).

a. If the team goes for 1 point after each touchdown,

what is the probability that the team wins?

loses? ties?

b. If the team goes for 2 points after each touchdown,

what is the probability that the team wins?

loses? ties?

c. Can you develop a strategy so that the coach’s

team has a probability of winning the game

that is greater than the probability of losing?

If so, explain your strategy and calculate the

probabilities of winning and losing the game.

30. ABSTRACT REASONING Assume that A and B are

independent events.

a. Explain why P(B) = P(B � A) and P(A) = P(A � B).

b. Can P(A and B) also be defi ned as P(B) ⋅ P(A � B)?

Justify your reasoning.

Maintaining Mathematical ProficiencyMaintaining Mathematical ProficiencySolve the equation. Check your solution. (Skills Review Handbook)

31. 9 — 10

x = 0.18 32. 1 — 4 x + 0.5x = 1.5 33. 0.3x −

3 —

5 x + 1.6 = 1.555



Section 10.3 Two-Way Tables and Probability 553

Two-Way Tables and Probability10.3

Essential QuestionEssential Question How can you construct and interpret

a two-way table?

Completing and Using a Two-Way Table

Work with a partner. A two-way table displays the same information as a Venn

diagram. In a two-way table, one category is represented by the rows and the other

category is represented by the columns.

The Venn diagram shows the results of a survey in which 80 students were asked

whether they play a musical instrument and whether they speak a foreign language.

Use the Venn diagram to complete the two-way table. Then use the two-way table to

answer each question.

Play an Instrument Do Not Play an Instrument Total

Speak a ForeignLanguage

Do Not Speak aForeign Language

Total

a. How many students play an instrument?

b. How many students speak a foreign language?

c. How many students play an instrument and speak a foreign language?

d. How many students do not play an instrument and do not speak a foreign language?

e. How many students play an instrument and do not speak a foreign language?

Two-Way Tables and Probability

Work with a partner. In Exploration 1, one student is selected at random from the

80 students who took the survey. Find the probability that the student

a. plays an instrument.

b. speaks a foreign language.

c. plays an instrument and speaks a foreign language.

d. does not play an instrument and does not speak a foreign language.

e. plays an instrument and does not speak a foreign language.

Conducting a Survey

Work with your class. Conduct a survey of the students in your class. Choose two

categories that are different from those given in Explorations 1 and 2. Then summarize

the results in both a Venn diagram and a two-way table. Discuss the results.

Communicate Your AnswerCommunicate Your Answer 4. How can you construct and interpret a two-way table?

5. How can you use a two-way table to determine probabilities?

MODELING WITH MATHEMATICS

To be profi cient in math, you need to identify important quantities in a practical situation and map their relationships using such tools as diagrams and two-way tables.

Survey of 80 Students

9

Play aninstrument

Speak aforeign

language

25

16

30



10.3 Lesson What You Will LearnWhat You Will Learn Make two-way tables.

Find relative and conditional relative frequencies.

Use conditional relative frequencies to fi nd conditional probabilities.

Making Two-Way TablesA two-way table is a frequency table that displays data collected from one source

that belong to two different categories. One category of data is represented by rows

and the other is represented by columns. Suppose you randomly survey freshmen and

sophomores about whether they are attending a school concert. A two-way table is one

way to organize your results.

Each entry in the table

is called a joint frequency.

The sums of the rows and

columns are called

marginal frequencies,

which you will fi nd in

Example 1.

Making a Two-Way Table

In another survey similar to the one above, 106 juniors and 114 seniors respond. Of

those, 42 juniors and 77 seniors plan on attending. Organize these results in a two-way

table. Then fi nd and interpret the marginal frequencies.

SOLUTION

Step 1 Find the joint frequencies. Because 42 of the 106 juniors are attending,

106 − 42 = 64 juniors are not attending. Because 77 of the 114 seniors

are attending, 114 − 77 = 37 seniors are not attending. Place each joint

frequency in its corresponding cell.

Step 2 Find the marginal frequencies. Create a new column and row for the sums.

Then add the entries and interpret the results.

Step 3 Find the sums of the marginal frequencies. Notice the sums 106 + 114 = 220

and 119 + 101 = 220 are equal. Place this value at the bottom right.


1. You randomly survey students about whether they are in favor of planting a

community garden at school. Of 96 boys surveyed, 61 are in favor. Of 88 girls

surveyed, 17 are against. Organize the results in a two-way table. Then fi nd and

interpret the marginal frequencies.

Attendance

Attending Not Attending

Cla

ss Freshman 25 44

Sophomore 80 32

joint frequencyREADING

A two-way table is also called a contingency table, or a two-way frequency table.

two-way table, p. 554joint frequency, p. 554marginal frequency, p. 554joint relative frequency,

p. 555marginal relative frequency,

p. 555conditional relative frequency,

p. 555

Previousconditional probability


Attendance

Attending Not Attending Total

Cla

ss Junior 42 64 106

Senior 77 37 114

Total 119 101 220

119 students are attending. 101 students are not attending.

106 juniors responded.

114 seniors responded.

220 students were surveyed.



Attendance

Attending Not Attending Total

Cla

ss

Junior 42

— 220

≈ 0.191 64

— 220

≈ 0.291 0.482

Senior 77

— 220

= 0.35 37

— 220

≈ 0.168 0.518

Total 0.541 0.459 1

Finding Joint and Marginal Relative Frequencies

Use the survey results in Example 1 to make a two-way table that shows the joint and

marginal relative frequencies.

SOLUTION

To fi nd the joint relative frequencies, divide each frequency by the total number of

students in the survey. Then fi nd the sum of each row and each column to fi nd the


About 29.1% of the students in the survey are juniors and are not attending the concert.

About 51.8% of the students in the survey are seniors.

Finding Conditional Relative Frequencies

Use the survey results in Example 1 to make a two-way table that shows the

conditional relative frequencies based on the row totals.

SOLUTION

Use the marginal relative frequency of each row to calculate the conditional relative

frequencies.

Attendance

Attending Not Attending

Cla

ss

Junior 0.191

— 0.482

≈ 0.396 0.291

— 0.482

≈ 0.604

Senior 0.35

— 0.518

≈ 0.676 0.168

— 0.518

≈ 0.324

Given that a student is a senior, the conditional relative frequency that he or she is not attending the concert is about 32.4%.

Finding Relative and Conditional Relative FrequenciesYou can display values in a two-way table as frequency counts (as in Example 1) or as

relative frequencies.

Core Core ConceptConceptRelative and Conditional Relative FrequenciesA joint relative frequency is the ratio of a frequency that is not in the total row or

the total column to the total number of values or observations.

A marginal relative frequency is the sum of the joint relative frequencies in a

row or a column.

A conditional relative frequency is the ratio of a joint relative frequency to the

marginal relative frequency. You can fi nd a conditional relative frequency using a

row total or a column total of a two-way table.

STUDY TIPTwo-way tables can display relative frequencies based on the total number of observations, the row totals, or the column totals.

INTERPRETING MATHEMATICAL RESULTS

Relative frequencies can be interpreted as probabilities. The probability that a randomly selected student is a junior and is not attending the concert is 29.1%.




2. Use the survey results in Monitoring Progress Question 1 to make a two-way table

that shows the joint and marginal relative frequencies.

3. Use the survey results in Example 1 to make a two-way table that shows the

conditional relative frequencies based on the column totals. Interpret the

conditional relative frequencies in the context of the problem.

4. Use the survey results in Monitoring Progress Question 1 to make a two-way table

that shows the conditional relative frequencies based on the row totals. Interpret

the conditional relative frequencies in the context of the problem.

Finding Conditional ProbabilitiesYou can use conditional relative frequencies to fi nd conditional probabilities.

Finding Conditional Probabilities

A satellite TV provider surveys customers in three cities. The survey asks whether

they would recommend the TV provider to a friend. The results, given as joint relative

frequencies, are shown in the two-way table.

a. What is the probability that a randomly selected

customer who is located in Glendale will recommend

the provider?

b. What is the probability that a randomly selected

customer who will not recommend the provider is

located in Long Beach?

c. Determine whether recommending the provider to a

friend and living in Long Beach are independent events.

SOLUTION

a. P(yes � Glendale) = P(Glendale and yes)

—— P(Glendale)

= 0.29 —

0.29 + 0.05 ≈ 0.853

So, the probability that a customer who is located in Glendale will recommend

the provider is about 85.3%.

b. P(Long Beach � no) = P(no and Long Beach)

—— P(no)

= 0.04 ——

0.05 + 0.03 + 0.04 ≈ 0.333

So, the probability that a customer who will not recommend the provider is

located in Long Beach is about 33.3%.

c. Use the formula P(B) = P(B � A) and compare P(Long Beach) and

P(Long Beach � yes).

P(Long Beach) = 0.32 + 0.04 = 0.36

P(Long Beach � yes) = P(Yes and Long Beach)

—— P(yes)

= 0.32 ——

0.29 + 0.27 + 0.32 ≈ 0.36

Because P(Long Beach) ≈ P(Long Beach � yes), the two events are

independent.

Location

Glendale Santa Monica Long Beach

Respon

se Yes 0.29 0.27 0.32

No 0.05 0.03 0.04

INTERPRETING MATHEMATICAL RESULTSThe probability 0.853 is a conditional relative frequency based on a column total. The condition is that the customer lives in Glendale.




5. In Example 4, what is the probability that a randomly selected customer who is

located in Santa Monica will not recommend the provider to a friend?

6. In Example 4, determine whether recommending the provider to a friend and

living in Santa Monica are independent events. Explain your reasoning.

Comparing Conditional Probabilities

A jogger wants to burn a certain number

of calories during his workout. He maps

out three possible jogging routes. Before

each workout, he randomly selects a

route, and then determines the number of

calories he burns and whether he reaches

his goal. The table shows his fi ndings.

Which route should he use?

SOLUTION

Step 1 Use the fi ndings to make a two-way

table that shows the joint and marginal

relative frequencies. There are a total

of 50 observations in the table.

Step 2 Find the conditional

probabilities by

dividing each joint

relative frequency in

the “Reaches Goal”

column by the marginal

relative frequency in its

corresponding row.

P(reaches goal � Route A) = P(Route A and reaches goal)

——— P(Route A)

= 0.22

— 0.34

≈ 0.647

P(reaches goal � Route B) = P(Route B and reaches goal)

——— P(Route B)

= 0.22

— 0.30

≈ 0.733

P(reaches goal � Route C) = P(Route C and reaches goal)

——— P(Route C)

= 0.24

— 0.36

≈ 0.667

Based on the sample, the probability that he reaches his goal is greatest when he

uses Route B. So, he should use Route B.


7. A manager is assessing three employees

in order to offer one of them a promotion.

Over a period of time, the manager

records whether the employees meet or

exceed expectations on their assigned

tasks. The table shows the manager’s

results. Which employee should be

offered the promotion? Explain.

Reaches Goal

Does Not Reach Goal

Route A ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇

Route B ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇ ∣̇̇̇∣̇̇∣̇̇∣̇

Route C ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇

Result

Reaches Goal

Does Not Reach Goal

Total

Ro

ute

A 0.22 0.12 0.34

B 0.22 0.08 0.30

C 0.24 0.12 0.36

Total 0.68 0.32 1

Exceed Expectations

Meet Expectations

Joy ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇̇∣̇̇∣̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇

Elena ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇̇∣̇

Sam ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ̇ ∣̇̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇




1. COMPLETE THE SENTENCE A(n) _____________ displays data collected from the same source

that belongs to two different categories.

2. WRITING Compare the defi nitions of joint relative frequency, marginal relative frequency, and

conditional relative frequency.


In Exercises 3 and 4, complete the two-way table.

3. Preparation

StudiedDid Not Study

Total

Grade Pass 6

Fail 10

Total 38 50

4. Response

Yes No Total

Ro

le Student 56

Teacher 7 10

Total 49

5. MODELING WITH MATHEMATICS You survey

171 males and 180 females at Grand Central Station

in New York City. Of those, 132 males and 151

females wash their hands after using the public rest

rooms. Organize these results in a two-way table.

Then fi nd and interpret the marginal frequencies. (See Example 1.)

6. MODELING WITH MATHEMATICS A survey asks

60 teachers and 48 parents whether school uniforms

reduce distractions in school. Of those, 49 teachers

and 18 parents say uniforms reduce distractions in

school. Organize these results in a two-way table.

Then fi nd and interpret the marginal frequencies.

USING STRUCTURE In Exercises 7 and 8, use the two-way table to create a two-way table that shows the joint and marginal relative frequencies.

7. Dominant Hand

Left Right Total

Gen

der

Female 11 104 115

Male 24 92 116

Total 35 196 231

8. Gender

Male Female Total

Expe

rien

ce Expert 62 6 68

Average 275 24 299

Novice 40 3 43

Total 377 33 410

9. MODELING WITH MATHEMATICS Use the survey

results from Exercise 5 to make a two-way table that

shows the joint and marginal relative frequencies. (See Example 2.)

10. MODELING WITH MATHEMATICS In a survey,

49 people received a fl u vaccine before the fl u season

and 63 people did not receive the vaccine. Of those

who receive the fl u vaccine, 16 people got the fl u.

Of those who did not receive the vaccine, 17 got the

fl u. Make a two-way table that shows the joint and





11. MODELING WITH MATHEMATICS A survey fi nds

that 110 people ate breakfast and 30 people skipped

breakfast. Of those who ate breakfast, 10 people felt

tired. Of those who skipped breakfast, 10 people

felt tired. Make a two-way table that shows the

conditional relative frequencies based on the

breakfast totals. (See Example 3.)

12. MODELING WITH MATHEMATICS Use the survey

results from Exercise 10 to make a two-way table that

shows the conditional relative frequencies based on

the fl u vaccine totals.

13. PROBLEM SOLVING Three different local hospitals

in New York surveyed their patients. The survey

asked whether the patient’s physician communicated

effi ciently. The results, given as joint relative

frequencies, are shown in the two-way table. (See Example 4.)

Location

Glens Falls Saratoga Albany

Respon

se Yes 0.123 0.288 0.338

No 0.042 0.077 0.131


patient located in Saratoga was satisfi ed with the

communication of the physician?


patient who was not satisfi ed with the physician’s

communication is located in Glens Falls?

c. Determine whether being satisfi ed with the

communication of the physician and living in

Saratoga are independent events.

14. PROBLEM SOLVING A researcher surveys a random

sample of high school students in seven states. The

survey asks whether students plan to stay in their

home state after graduation. The results, given as joint

relative frequencies, are shown in the two-way table.

Location

NebraskaNorth

CarolinaOther States

Respon

se Yes 0.044 0.051 0.056

No 0.400 0.193 0.256


student who lives in Nebraska plans to stay in his

or her home state after graduation?


student who does not plan to stay in his or her home

state after graduation lives in North Carolina?

c. Determine whether planning to stay in their home

state and living in Nebraska are independent events.

ERROR ANALYSIS In Exercises 15 and 16, describe and correct the error in fi nding the given conditional probability.

City

Tokyo LondonWashington,

D.C.Total

Respon

se Yes 0.049 0.136 0.171 0.356

No 0.341 0.112 0.191 0.644

Total 0.39 0.248 0.362 1

15. P(yes � Tokyo)

P(yes | Tokyo) = P(Tokyo and yes) —— P(Tokyo)

= 0.049 — 0.356

≈ 0.138

✗

16. P(London � no)

P(London | no) = P(no and London) —— P(London)

= 0.112 — 0.248

≈ 0.452

✗

17. PROBLEM SOLVING You want to fi nd the quickest

route to school. You map out three routes. Before

school, you randomly select a route and record

whether you are late or on time. The table shows your

fi ndings. Assuming you leave at the same time each

morning, which route should you use? Explain. (See Example 5.)

On Time Late

Route A ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇ ∣̇̇̇∣̇̇∣̇̇∣̇Route B ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇ ∣̇̇̇∣̇̇∣̇Route C ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇ ∣̇̇̇∣̇̇∣̇̇∣̇

18. PROBLEM SOLVING A teacher is assessing three

groups of students in order to offer one group a prize.

Over a period of time, the teacher records whether the

groups meet or exceed expectations on their assigned

tasks. The table shows the teacher’s results. Which

group should be awarded the prize? Explain.

Exceed Expectations

Meet Expectations

Group 1 ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇ ∣̇̇̇∣̇̇∣̇̇∣̇Group 2 ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇̇∣̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇

Group 3 ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇̇∣̇̇∣̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇



19. OPEN-ENDED Create and conduct a survey in your

class. Organize the results in a two-way table. Then

create a two-way table that shows the joint and

marginal frequencies.

20. HOW DO YOU SEE IT? A research group surveys

parents and coaches of high school students about

whether competitive sports are important in school.

The two-way table shows the results of the survey.

Role

Parent Coach Total

Impo

rtan

t

Yes 880 456 1336

No 120 45 165

Total 1000 501 1501

a. What does 120 represent?

b. What does 1336 represent?

c. What does 1501 represent?

21. MAKING AN ARGUMENT Your friend uses the table

below to determine which workout routine is the best.

Your friend decides that Routine B is the best option

because it has the fewest tally marks in the “Does Not

Reach Goal” column. Is your friend correct? Explain

your reasoning.

Reached Goal

Does Not Reach Goal

Routine A ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇̇∣̇

Routine B ∣̇̇̇∣̇̇∣̇̇∣̇ ∣̇̇̇∣̇

Routine C ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇̇∣̇ ∣̇̇̇∣̇̇∣̇̇∣̇

22. MODELING WITH MATHEMATICS A survey asks

students whether they prefer math class or science

class. Of the 150 male students surveyed, 62% prefer

math class over science class. Of the female students

surveyed, 74% prefer math. Construct a two-way table

to show the number of students in each category if

350 students were surveyed.

23. MULTIPLE REPRESENTATIONS Use the Venn diagram

to construct a two-way table. Then use your table to

answer the questions.

92

Dog Owner Cat Owner

57 2536


person does not own either pet?


person who owns a dog also owns a cat?

24. WRITING Compare two-way tables and Venn

diagrams. Then describe the advantages and

disadvantages of each.

25. PROBLEM SOLVING A company creates a new snack,

N, and tests it against its current leader, L. The table

shows the results.

Prefer L Prefer N

Current L Consumer 72 46

Not Current L Consumer 52 114

The company is deciding whether it should try to

improve the snack before marketing it, and to whom

the snack should be marketed. Use probability to

explain the decisions the company should make when

the total size of the snack’s market is expected to

(a) change very little, and (b) expand very rapidly.

26. THOUGHT PROVOKING Bayes’ Theorem is given by

P(A � B) = P(B � A) ⋅ P(A)

—— P(B)

.

Use a two-way table to write an example of Bayes’

Theorem.

Maintaining Mathematical ProficiencyMaintaining Mathematical ProficiencyDraw a Venn diagram of the sets described. (Skills Review Handbook)

27. Of the positive integers less than 15, set A consists of the factors of 15 and set B consists of

all odd numbers.

28. Of the positive integers less than 14, set A consists of all prime numbers and set B consists of

all even numbers.

29. Of the positive integers less than 24, set A consists of the multiples of 2 and set B consists of

all the multiples of 3.



561561

10.1–10.3 What Did You Learn?

• Write down important information on note cards.

• Memorize the information on the note cards, placing the ones containing information you know in one stack and the ones containing information you do not know in another stack. Keep working on the information you do not know.

Core VocabularyCore Vocabularyprobability experiment, p. 538outcome, p. 538event, p. 538sample space, p. 538probability of an event, p. 538theoretical probability, p. 539

geometric probability, p. 540experimental probability, p. 541independent events, p. 546dependent events, p. 547conditional probability, p. 547two-way table, p. 554

joint frequency, p. 554marginal frequency, p. 554joint relative frequency, p. 555marginal relative frequency, p. 555conditional relative frequency,

p. 555

Core ConceptsCore ConceptsSection 10.1Theoretical Probabilities, p. 538Probability of the Complement of an Event, p. 539Experimental Probabilities, p. 541

Section 10.2Probability of Independent Events, p. 546Probability of Dependent Events, p. 547Finding Conditional Probabilities, p. 549

Section 10.3Making Two-Way Tables, p. 554Relative and Conditional Relative Frequencies, p. 555

Mathematical PracticesMathematical Practices1. How can you use a number line to analyze the error in Exercise 12 on page 542?

2. Explain how you used probability to correct the fl awed logic of your friend in

Exercise 21 on page 560.

Study Skills

Making a Mental Cheat Sheet

hsnb_alg2_pe_10mc.indd 561hsnb_alg2_pe_10mc.indd 561 2/5/15 2:11 PM2/5/15 2:11 PM


10.1–10.3 Quiz

1. You randomly draw a marble out of a bag containing 8 green marbles, 4 blue marbles,

12 yellow marbles, and 10 red marbles. Find the probability of drawing a marble that is

not yellow. (Section 10.1)

Find P( — A ). (Section 10.1)

2. P(A) = 0.32 3. P(A) = 8 —

9 4. P(A) = 0.01

5. You roll a six-sided die 30 times. A 5 is rolled 8 times. What is the theoretical probability

of rolling a 5? What is the experimental probability of rolling a 5? (Section 10.1)

6. Events A and B are independent. Find the missing probability. (Section 10.2)

P(A) = 0.25

P(B) = _____

P(A and B) = 0.05

7. Events A and B are dependent. Find the missing probability. (Section 10.2)

P(A) = 0.6

P(B � A) = 0.2

P(A and B) = _____

8. Find the probability that a dart thrown at the circular target shown will hit the given region.

Assume the dart is equally likely to hit any point inside the target. (Section 10.1)

a. the center circle

b. outside the square

c. inside the square but outside the center circle

9. A survey asks 13-year-old and 15-year-old students about their

eating habits. Four hundred students are surveyed, 100 male students

and 100 female students from each age group. The bar graph shows

the number of students who said they eat fruit every day.

(Section 10.2)

a. Find the probability that a female student, chosen at random

from the students surveyed, eats fruit every day.

b. Find the probability that a 15-year-old student, chosen at

random from the students surveyed, eats fruit every day.

10. There are 14 boys and 18 girls in a class. The teacher allows the

students to vote whether they want to take a test on Friday or on

Monday. A total of 6 boys and 10 girls vote to take the test on

Friday. Organize the information in a two-way table. Then fi nd

and interpret the marginal frequencies. (Section 10.3)

11. Three schools compete in a cross country invitational. Of the 15 athletes on your team,

9 achieve their goal times. Of the 20 athletes on the home team, 6 achieve their goal

times. On your rival’s team, 8 of the 13 athletes achieve their goal times. Organize the

information in a two-way table. Then determine the probability that a randomly selected

runner who achieves his or her goal time is from your school. (Section 10.3)

13 years old 15 years old

Age

Nu

mb

er o

f st

ud

ents

50

52

54

56

58

60

62

64

Survey Results

MaleFemale

6

2

6

hsnb_alg2_pe_10mc.indd 562hsnb_alg2_pe_10mc.indd 562 2/5/15 2:11 PM2/5/15 2:11 PM

Section 10.4 Probability of Disjoint and Overlapping Events 563

Essential QuestionEssential Question How can you fi nd probabilities of disjoint and

overlapping events?

Two events are disjoint, or mutually exclusive, when they have no outcomes

in common. Two events are overlapping when they have one or more outcomes

in common.

Disjoint Events and Overlapping Events

Work with a partner. A six-sided die is rolled. Draw a Venn diagram that relates

the two events. Then decide whether the events are disjoint or overlapping.

a. Event A: The result is an even number.

Event B: The result is a prime number.

b. Event A: The result is 2 or 4.

Event B: The result is an odd number.

Finding the Probability that Two Events Occur

Work with a partner. A six-sided die is rolled. For each pair of events,

fi nd (a) P(A), (b) P(B), (c) P(A and B), and (d) P(A or B).

a. Event A: The result is an even number.

Event B: The result is a prime number.

b. Event A: The result is 2 or 4.

Event B: The result is an odd number.

Discovering Probability Formulas


a. In general, if event A and event B are disjoint, then what is the probability that

event A or event B will occur? Use a Venn diagram to justify your conclusion.

b. In general, if event A and event B are overlapping, then what is the probability that

event A or event B will occur? Use a Venn diagram to justify your conclusion.

c. Conduct an experiment using a six-sided die. Roll the die 50 times and record the

results. Then use the results to fi nd the probabilities described in Exploration 2.

How closely do your experimental probabilities compare to the theoretical

probabilities you found in Exploration 2?

Communicate Your AnswerCommunicate Your Answer 4. How can you fi nd probabilities of disjoint and overlapping events?

5. Give examples of disjoint events and overlapping events that do not involve dice.

MODELING WITH MATHEMATICSTo be profi cient in math, you need to map the relationships between important quantities in a practical situation using such tools as diagrams.

Probability of Disjoint and Overlapping Events

10.4



10.4 Lesson What You Will LearnWhat You Will Learn Find probabilities of compound events.

Use more than one probability rule to solve real-life problems.

Compound EventsWhen you consider all the outcomes for either of two events A and B, you form the

union of A and B, as shown in the fi rst diagram. When you consider only the outcomes

shared by both A and B, you form the intersection of A and B, as shown in the second

diagram. The union or intersection of two events is called a compound event.

Union of A and B

A B

Intersection of A and B

A B

Intersection of A and Bis empty.

A B

To fi nd P(A or B) you must consider what outcomes, if any, are in the intersection of A

and B. Two events are overlapping when they have one or more outcomes in common,

as shown in the fi rst two diagrams. Two events are disjoint, or mutually exclusive,

when they have no outcomes in common, as shown in the third diagram.

Finding the Probability of Disjoint Events

A card is randomly selected from a standard deck of 52 playing cards. What is the

probability that it is a 10 or a face card?

SOLUTION

Let event A be selecting a 10 and event B be selecting a face card. From the diagram,

A has 4 outcomes and B has 12 outcomes. Because A and B are disjoint, the

probability is

P(A or B) = P(A) + P(B) Write disjoint probability formula.

= 4 —

52 +

12 —

52 Substitute known probabilities.

= 16

— 52

Add.

= 4 —

13 Simplify.

≈ 0.308. Use a calculator.

compound event, p. 564overlapping events, p. 564disjoint or mutually exclusive

events, p. 564

PreviousVenn diagram


Core Core ConceptConceptProbability of Compound EventsIf A and B are any two events, then the probability of A or B is

P(A or B) = P(A) + P(B) − P(A and B).

If A and B are disjoint events, then the probability of A or B is

P(A or B) = P(A) + P(B).

STUDY TIPIf two events A and B are overlapping, then the outcomes in the intersection of A and B are counted twice when P(A) and P(B) are added. So, P(A and B) must be subtracted from the sum.

A B

10♠10♣10♦10♥ Κ♠Κ♥Q♠Q♥

Κ♦Κ♣Q♦Q♣J♠

J♣J♦J♥



Finding the Probability of Overlapping Events

A card is randomly selected from a standard deck of 52 playing cards. What is the

probability that it is a face card or a spade?

SOLUTION

Let event A be selecting a face card and event B

be selecting a spade. From the diagram, A has

12 outcomes and B has 13 outcomes. Of these,

3 outcomes are common to A and B. So, the

probability of selecting a face card or a spade is

P(A or B) = P(A) + P(B) − P(A and B) Write general formula.

= 12

— 52

+ 13

— 52

− 3 —


= 22

— 52

Add.

= 11

— 26

Simplify.

≈ 0.423. Use a calculator.

Using a Formula to Find P (A and B)

Out of 200 students in a senior class, 113 students are either varsity athletes or on the

honor roll. There are 74 seniors who are varsity athletes and 51 seniors who are on

the honor roll. What is the probability that a randomly selected senior is both a varsity

athlete and on the honor roll?

SOLUTION

Let event A be selecting a senior who is a varsity athlete and event B be selecting a

senior on the honor roll. From the given information, you know that P(A) = 74

— 200

,

P(B) = 51

— 200

, and P(A or B) = 113

— 200

. The probability that a randomly selected senior is

both a varsity athlete and on the honor roll is P(A and B).

P(A or B) = P(A) + P(B) − P(A and B) Write general formula.

113

— 200

= 74

— 200

+ 51

— 200

− P(A and B) Substitute known probabilities.

P(A and B) = 74

— 200

+ 51

— 200

− 113

— 200

Solve for P(A and B).

P(A and B) = 12

— 200

Simplify.

P(A and B) = 3 —

50 , or 0.06 Simplify.


A card is randomly selected from a standard deck of 52 playing cards. Find the probability of the event.

1. selecting an ace or an 8 2. selecting a 10 or a diamond

3. WHAT IF? In Example 3, suppose 32 seniors are in the band and 64 seniors are

in the band or on the honor roll. What is the probability that a randomly selected

senior is both in the band and on the honor roll?

COMMON ERRORWhen two events A and B overlap, as in Example 2, P(A or B) does not equal P(A) + P(B).

A B10♠9♠8♠

3♠2♠A♠7♠6♠5♠4♠

Κ♥Q♥J♥Κ♦Q♦J♦Κ♣Q♣J♣

Κ♠Q♠J♠



Using More Than One Probability RuleIn the fi rst four sections of this chapter, you have learned several probability rules.

The solution to some real-life problems may require the use of two or more of these

probability rules, as shown in the next example.

Solving a Real-Life Problem

The American Diabetes Association estimates that 8.3% of people in the United States

have diabetes. Suppose that a medical lab has developed a simple diagnostic test

for diabetes that is 98% accurate for people who have the disease and 95% accurate

for people who do not have it. The medical lab gives the test to a randomly selected

person. What is the probability that the diagnosis is correct?

SOLUTION

Let event A be “person has diabetes” and event B be “correct diagnosis.” Notice that

the probability of B depends on the occurrence of A, so the events are dependent.

When A occurs, P(B) = 0.98. When A does not occur, P(B) = 0.95.

A probability tree diagram, where the probabilities are given along the branches, can

help you see the different ways to obtain a correct diagnosis. Use the complements of

events A and B to complete the diagram, where — A is “person does not have diabetes”

and — B is “incorrect diagnosis.” Notice that the probabilities for all branches from the

same point must sum to 1.

Population of United States

Event A:Person hasdiabetes.

Event A:Person does not have diabetes.

Event B:Correct diagnosis

Event B:Correct diagnosis

Event B:Incorrect diagnosis

0.083

0.917

0.05

0.95

0.02

0.98

Event B:Incorrect diagnosis

To fi nd the probability that the diagnosis is correct, follow the branches leading to

event B.

P(B) = P(A and B) + P( — A and B) Use tree diagram.

= P(A) ⋅ P(B � A) + P( — A ) ⋅ P(B � — A ) Probability of dependent events

= (0.083)(0.98) + (0.917)(0.95) Substitute.

≈ 0.952 Use a calculator.

The probability that the diagnosis is correct is about 0.952, or 95.2%.


4. In Example 4, what is the probability that the diagnosis is incorrect?

5. A high school basketball team leads at halftime in 60% of the games in a season.

The team wins 80% of the time when they have the halftime lead, but only 10% of

the time when they do not. What is the probability that the team wins a particular

game during the season?




In Exercises 3–6, events A and B are disjoint. Find P(A or B).

3. P(A) = 0.3, P(B) = 0.1 4. P(A) = 0.55, P(B) = 0.2

5. P(A) = 1 —

3 , P(B) =

1 —

4 6. P(A) =

2 —

3 , P(B) =

1 —

5

7. PROBLEM SOLVING Your dart is equally

likely to hit any point

inside the board shown.

You throw a dart and

pop a balloon. What

is the probability that

the balloon is red or

blue? (See Example 1.)

8. PROBLEM SOLVING You and your friend are among

several candidates running for class president. You

estimate that there is a 45% chance you will win

and a 25% chance your friend will win. What is the

probability that you or your friend win the election?

9. PROBLEM SOLVING You are performing an

experiment to determine how well plants grow

under different light sources. Of the 30 plants in

the experiment, 12 receive visible light, 15 receive

ultraviolet light, and 6 receive both visible and

ultraviolet light. What is the probability that a plant in

the experiment receives visible or ultraviolet light? (See Example 2.)

10. PROBLEM SOLVING Of 162 students honored at

an academic awards banquet, 48 won awards for

mathematics and 78 won awards for English. There

are 14 students who won awards for both mathematics

and English. A newspaper chooses a student at

random for an interview. What is the probability that

the student interviewed won an award for English or

mathematics?

ERROR ANALYSIS In Exercises 11 and 12, describe and correct the error in fi nding the probability of randomly drawing the given card from a standard deck of 52 playing cards.

11. P(heart or face card) = P(heart) + P(face card)

= 13 — 52 + 12

— 52 = 25 — 52

✗

12. P(club or 9) = P(club) + P(9) + P(club and 9)

= 13 — 52 + 4

— 52 + 1 — 52 = 9

— 26 ✗

In Exercises 13 and 14, you roll a six-sided die. Find P(A or B).

13. Event A: Roll a 6.

Event B: Roll a prime number.

14. Event A: Roll an odd number.

Event B: Roll a number less than 5.


1. WRITING Are the events A and — A disjoint? Explain. Then give an example of a real-life event

and its complement.

2. DIFFERENT WORDS, SAME QUESTION Which is different? Find “both” answers.

How many outcomes are in the intersection of A and B?

How many outcomes are shared by both A and B?

How many outcomes are in the union of A and B?

How many outcomes in B are also in A?


A B



15. DRAWING CONCLUSIONS A group of 40 trees in a

forest are not growing properly. A botanist determines

that 34 of the trees have a

disease or are being damaged

by insects, with 18 trees having

a disease and 20 being damaged

by insects. What is the

probability that a randomly

selected tree has both a disease

and is being damaged by

insects? (See Example 3.)

16. DRAWING CONCLUSIONS A company paid overtime

wages or hired temporary help during 9 months of

the year. Overtime wages were paid during 7 months,

and temporary help was hired during 4 months. At the

end of the year, an auditor examines the accounting

records and randomly selects one month to check the

payroll. What is the probability that the auditor will

select a month in which the company paid overtime

wages and hired temporary help?

17. DRAWING CONCLUSIONS A company is focus testing

a new type of fruit drink. The focus group is 47%

male. Of the responses, 40% of the males and 54% of

the females said they would buy the fruit drink. What

is the probability that a randomly selected person

would buy the fruit drink? (See Example 4.)

18. DRAWING CONCLUSIONS The Redbirds trail the

Bluebirds by one goal with 1 minute left in the hockey

game. The Redbirds’ coach must decide whether to

remove the goalie and add a frontline player. The

probabilities of each team scoring are shown

in the table.

Goalie No goalie

Redbirds score 0.1 0.3

Bluebirds score 0.1 0.6

a. Find the probability that the Redbirds score and

the Bluebirds do not score when the coach leaves

the goalie in.

b. Find the probability that the Redbirds score and

the Bluebirds do not score when the coach takes

the goalie out.

c. Based on parts (a) and (b), what should the

coach do?

19. PROBLEM SOLVING You can win concert tickets from

a radio station if you are the fi rst person to call when

the song of the day is played, or if you are the fi rst

person to correctly answer the trivia question. The song

of the day is announced at a random time between

7:00 and 7:30 a.m. The trivia question is asked at

a random time between 7:15 and 7:45 a.m. You

begin listening to the radio station at 7:20. Find the

probability that you miss the announcement of the

song of the day or the trivia question.

20. HOW DO YOU SEE IT? Are events A and B

disjoint events?

Explain your

reasoning.

21. PROBLEM SOLVING You take a bus from your

neighborhood to your school. The express bus arrives

at your neighborhood at a random time between

7:30 and 7:36 a.m. The local bus arrives at your

neighborhood at a random time between 7:30 and

7:40 a.m. You arrive at the bus stop at 7:33 a.m. Find

the probability that you missed both the express bus

and the local bus.

22. THOUGHT PROVOKING Write a general rule

for fi nding P(A or B or C) for (a) disjoint and

(b) overlapping events A, B, and C.

23. MAKING AN ARGUMENT A bag contains 40 cards

numbered 1 through 40 that are either red or blue. A

card is drawn at random and placed back in the bag.

This is done four times. Two red cards are drawn,

numbered 31 and 19, and two blue cards are drawn,

numbered 22 and 7. Your friend concludes that red

cards and even numbers must be mutually exclusive.

Is your friend correct? Explain.

Maintaining Mathematical ProficiencyMaintaining Mathematical ProficiencyWrite the fi rst six terms of the sequence. (Section 8.5)

24. a1 = 4, an = 2an − 1 + 3 25. a1 = 1, an = n(n − 1)

— an − 1

26. a1 = 2, a2 = 6, an = (n + 1)an −1 ——

an − 2


d

A B


Section 10.5 Permutations and Combinations 569

Permutations and Combinations10.5

Essential QuestionEssential Question How can a tree diagram help you visualize the

number of ways in which two or more events can occur?

Reading a Tree Diagram

Work with a partner. Two coins are fl ipped and the spinner

is spun. The tree diagram shows the possible outcomes.

H

H T H T

T

2 312 31 2 31 2 31

Coin is fl ipped.

Coin is fl ipped.

Spinner is spun.

a. How many outcomes are possible?

b. List the possible outcomes.

Reading a Tree Diagram

Work with a partner. Consider the tree diagram below.

2 31 2 31

BA

BA BA BA BA BA BA BA BA BA BA BA BA

X Y X Y X Y X Y X Y X Y

a. How many events are shown? b. What outcomes are possible for each event?

c. How many outcomes are possible? d. List the possible outcomes.

Writing a Conjecture


a. Consider the following general problem: Event 1 can occur in m ways and event 2

can occur in n ways. Write a conjecture about the number of ways the two events

can occur. Explain your reasoning.

b. Use the conjecture you wrote in part (a) to write a conjecture about the number of

ways more than two events can occur. Explain your reasoning.

c. Use the results of Explorations 1(a) and 2(c) to verify your conjectures.

Communicate Your AnswerCommunicate Your Answer 4. How can a tree diagram help you visualize the number of ways in which two

or more events can occur?

5. In Exploration 1, the spinner is spun a second time. How many outcomes

are possible?

CONSTRUCTING VIABLE ARGUMENTS

To be profi cient in math, you need to make conjectures and build a logical progression of statements to explore the truth of your conjectures.

3

21

3



10.5 Lesson What You Will LearnWhat You Will Learn Use the formula for the number of permutations.

Use the formula for the number of combinations.

Use combinations and the Binomial Theorem to expand binomials.

PermutationsA permutation is an arrangement of objects in which order is important. For instance,

the 6 possible permutations of the letters A, B, and C are shown.

ABC ACB BAC BCA CAB CBA

Counting Permutations

Consider the number of permutations of the letters in the word JULY. In how many

ways can you arrange (a) all of the letters and (b) 2 of the letters?

SOLUTION

a. Use the Fundamental Counting Principle to fi nd the number of permutations of the

letters in the word JULY.

Number of

permutations = ( Choices for

1st letter ) ( Choices for

2nd letter ) ( Choices for

3rd letter ) ( Choices for

4th letter )

= 4 ⋅ 3 ⋅ 2 ⋅ 1

= 24

There are 24 ways you can arrange all of the letters in the word JULY.

b. When arranging 2 letters of the word JULY, you have 4 choices for the fi rst letter

and 3 choices for the second letter.

Number of

permutations = ( Choices for

1st letter ) ( Choices for

2nd letter )

= 4 ⋅ 3

= 12

There are 12 ways you can arrange 2 of the letters in the word JULY.


1. In how many ways can you arrange the letters in the word HOUSE?

2. In how many ways can you arrange 3 of the letters in the word MARCH?

In Example 1(a), you evaluated the expression 4 ⋅ 3 ⋅ 2 ⋅ 1. This expression can be

written as 4! and is read “4 factorial.” For any positive integer n, the product of the

integers from 1 to n is called n factorial and is written as

n! = n ⋅ (n − 1) ⋅ (n − 2) ⋅ . . . ⋅ 3 ⋅ 2 ⋅ 1.

As a special case, the value of 0! is defi ned to be 1.

In Example 1(b), you found the permutations of 4 objects taken 2 at a time. You can

fi nd the number of permutations using the formulas on the next page.

REMEMBERFundamental Counting Principle: If one event can occur in m ways and another event can occur in n ways, then the number of ways that both events can occur is m ⋅ n. The Fundamental Counting Principle can be extended to three or more events.

permutation, p. 570n factorial, p. 570combination, p. 572Binomial Theorem, p. 574

PreviousFundamental Counting

PrinciplePascal’s Triangle




Using a Permutations Formula

Ten horses are running in a race. In how many different ways can the horses fi nish

fi rst, second, and third? (Assume there are no ties.)

SOLUTION

To fi nd the number of permutations of 3 horses chosen from 10, fi nd 10P3.

10P3 = 10! —

(10 − 3)! Permutations formula

= 10!

— 7!

Subtract.

= 10 ⋅ 9 ⋅ 8 ⋅ 7!

—— 7!

Expand factorial. Divide out common factor, 7!.

= 720 Simplify.

There are 720 ways for the horses to fi nish fi rst, second, and third.

Finding a Probability Using Permutations

For a town parade, you will ride on a fl oat with your soccer team. There are 12 fl oats

in the parade, and their order is chosen at random. Find the probability that your fl oat

is fi rst and the fl oat with the school chorus is second.

SOLUTION

Step 1 Write the number of possible outcomes as the number of permutations of the

12 fl oats in the parade. This is 12P12 = 12!.

Step 2 Write the number of favorable outcomes as the number of permutations of the

other fl oats, given that the soccer team is fi rst and the chorus is second. This

is 10P10 = 10!.

Step 3 Find the probability.

P(soccer team is 1st, chorus is 2nd) = 10!

— 12!

Form a ratio of favorable to possible outcomes.

= 10! ——

12 ⋅ 11 ⋅ 10!

Expand factorial. Divide out common factor, 10!.

= 1 —

132 Simplify.

Core Core ConceptConceptPermutationsFormulas

The number of permutations of

n objects is given by

nPn = n!.

Examples


4 objects is

4P4 = 4! = 4 ⋅ 3 ⋅ 2 ⋅ 1 = 24.


n objects taken r at a time, where

r ≤ n, is given by

nPr = n! —

(n − r)! .


4 objects taken 2 at a time is

4P2 = 4! —

(4 − 2)! =

4 ⋅ 3 ⋅ 2! —

2! = 12.

USING A GRAPHING CALCULATORMost graphing calculators can calculate permutations.

4 nPr 4

24

4 nPr 2

12

STUDY TIPWhen you divide out common factors, remember that 7! is a factor of 10!.




3. WHAT IF? In Example 2, suppose there are 8 horses in the race. In how many

different ways can the horses fi nish fi rst, second, and third? (Assume there are

no ties.)

4. WHAT IF? In Example 3, suppose there are 14 fl oats in the parade. Find the

probability that the soccer team is fi rst and the chorus is second.

CombinationsA combination is a selection of objects in which order is not important. For instance,

in a drawing for 3 identical prizes, you would use combinations, because the order

of the winners would not matter. If the prizes were different, then you would use

permutations, because the order would matter.

Counting Combinations

Count the possible combinations of 2 letters chosen from the list A, B, C, D.

SOLUTION

List all of the permutations of 2 letters from the list A, B, C, D. Because order is not

important in a combination, cross out any duplicate pairs.

AB AC AD BA BC BD

CA CB CD DA DB DC

There are 6 possible combinations of 2 letters from the list A, B, C, D.


5. Count the possible combinations of 3 letters chosen from the list A, B, C, D, E.

In Example 4, you found the number of combinations of objects by making

an organized list. You can also fi nd the number of combinations using the

following formula.

BD and DB are the same pair.

Core Core ConceptConceptCombinationsFormula The number of combinations of n objects taken r at a time,

where r ≤ n, is given by

nCr = n! —

(n − r)! ⋅ r! .

Example The number of combinations of 4 objects taken 2 at a time is

4C2 = 4! ——

(4 − 2)! ⋅ 2! =

4 ⋅ 3 ⋅ 2! —

2! ⋅ (2 ⋅ 1) = 6.

USING A GRAPHING CALCULATOR

Most graphing calculators can calculate combinations.

4 nCr 2

6



Using the Combinations Formula

You order a sandwich at a restaurant. You can choose 2 side dishes from a list of 8.

How many combinations of side dishes are possible?

SOLUTION

The order in which you choose the side dishes is not important. So, to fi nd the number

of combinations of 8 side dishes taken 2 at a time, fi nd 8C2.

8C2 = 8! ——

(8 − 2)! ⋅ 2! Combinations formula

= 8! —

6! ⋅ 2! Subtract.

= 8 ⋅ 7 ⋅ 6!

— 6! ⋅ (2 ⋅ 1)

Expand factorials. Divide out common factor, 6!.

= 28 Multiply.

There are 28 different combinations of side dishes you can order.

Finding a Probability Using Combinations

A yearbook editor has selected 14 photos, including one of you and one of your friend,

to use in a collage for the yearbook. The photos are placed at random. There is room

for 2 photos at the top of the page. What is the probability that your photo and your

friend’s photo are the 2 placed at the top of the page?

SOLUTION

Step 1 Write the number of possible outcomes as the number of combinations of

14 photos taken 2 at a time, or 14C2, because the order in which the photos

are chosen is not important.

14C2 = 14! ——

(14 − 2)! ⋅ 2! Combinations formula

= 14! —

12! ⋅ 2! Subtract.

= 14 ⋅ 13 ⋅ 12!

—— 12! ⋅ (2 ⋅ 1)


= 91 Multiply.

Step 2 Find the number of favorable outcomes. Only one of the possible

combinations includes your photo and your friend’s photo.

Step 3 Find the probability.

P(your photo and your friend’s photos are chosen) = 1 —

91


6. WHAT IF? In Example 5, suppose you can choose 3 side dishes out of the list of

8 side dishes. How many combinations are possible?

7. WHAT IF? In Example 6, suppose there are 20 photos in the collage. Find the

probability that your photo and your friend’s photo are the 2 placed at the top

of the page.

Check

8 nCr 2

28



Binomial ExpansionsIn Section 4.2, you used Pascal’s Triangle to fi nd binomial expansions. The table

shows that the coeffi cients in the expansion of (a + b)n correspond to combinations.

n Pascal’s Triangle Pascal’s Triangle Binomial Expansion as Numbers as Combinations

0th row 0 1 0C0 (a + b)0 = 1

1st row 1 1 1 1C0 1C1 (a + b)1 = 1a + 1b

2nd row 2 1 2 1 2C0 2C1 2C2 (a + b)2 = 1a2 + 2ab + 1b2

3rd row 3 1 3 3 1 3C0 3C1 3C2 3C3 (a + b)3 = 1a3 + 3a2b + 3ab2 + 1b3

The results in the table are generalized in the Binomial Theorem.

Using the Binomial Theorem

a. Use the Binomial Theorem to write the expansion of (x2 + y)3.

b. Find the coeffi cient of x4 in the expansion of (3x + 2)10.

SOLUTION

a. (x2 + y)3 = 3C0(x2)3y0 + 3C1(x2)2y1 + 3C2(x2)1y2 + 3C3(x2)0y3

= (1)(x6)(1) + (3)(x4)(y1) + (3)(x2)(y2) + (1)(1)(y3)

= x6 + 3x4y + 3x2y2 + y3

b. From the Binomial Theorem, you know

(3x + 2)10 = 10C0(3x)10(2)0 + 10C1(3x)9(2)1 + … + 10C10(3x)0(2)10.

Each term in the expansion has the form 10Cr(3x)10 − r(2)r. The term containing x4

occurs when r = 6.

10C6(3x)4(2)6 = (210)(81x4)(64) = 1,088,640x4

The coeffi cient of x4 is 1,088,640.


8. Use the Binomial Theorem to write the expansion of (a) (x + 3)5 and

(b) (2p − q)4.

9. Find the coeffi cient of x5 in the expansion of (x − 3)7.

10. Find the coeffi cient of x3 in the expansion of (2x + 5)8.

Core Core ConceptConceptThe Binomial TheoremFor any positive integer n, the binomial expansion of (a + b)n is

(a + b)n = nC0 anb0 + nC1 an − 1b1 + nC2 an − 2b2 + … + nCn a0bn.

Notice that each term in the expansion of (a + b)n has the form nCr an − rbr,

where r is an integer from 0 to n.




In Exercises 3– 8, fi nd the number of ways you can arrange (a) all of the letters and (b) 2 of the letters in the given word. (See Example 1.)

3. AT 4. TRY

5. ROCK 6. WATER

7. FAMILY 8. FLOWERS

In Exercises 9–16, evaluate the expression.

9. 5P2 10. 7P3

11. 9P1 12. 6P5

13. 8P6 14. 12P0

15. 30P2 16. 25P5

17. PROBLEM SOLVING Eleven students are competing

in an art contest. In how many different ways can

the students fi nish fi rst, second, and third? (See Example 2.)

18. PROBLEM SOLVING Six friends go to a movie theater.

In how many different ways can they sit together in a

row of 6 empty seats?

19. PROBLEM SOLVING You and your friend are 2 of

8 servers working a shift in a restaurant. At the

beginning of the shift, the manager randomly assigns

one section to each server. Find the probability that

you are assigned Section 1 and your friend is assigned

Section 2. (See Example 3.)

20. PROBLEM SOLVING You make 6 posters to hold up at

a basketball game. Each poster has a letter of the word

TIGERS. You and 5 friends sit next to each other in a

row. The posters are distributed at random. Find the

probability that TIGERS is spelled correctly when

you hold up the posters.

In Exercises 21–24, count the possible combinations of r letters chosen from the given list. (See Example 4.)

21. A, B, C, D; r = 3 22. L, M, N, O; r = 2

23. U, V, W, X, Y, Z; r = 3 24. D, E, F, G, H; r = 4

In Exercises 25–32, evaluate the expression.

25. 5C1 26. 8C5

27. 9C9 28. 8C6

29. 12C3 30. 11C4

31. 15C8 32. 20C5


1. COMPLETE THE SENTENCE An arrangement of objects in which order is important is called

a(n) __________.

2. WHICH ONE DOESN’T BELONG? Which expression does not belong with the other three? Explain

your reasoning.

7C27C5 7! —

2! ⋅ 5!

7! —

(7 − 2)!




33. PROBLEM SOLVING Each year, 64 golfers participate

in a golf tournament. The golfers play in groups of 4.

How many groups of 4 golfers are possible? (See Example 5.)

34. PROBLEM SOLVING You want to purchase vegetable

dip for a party. A grocery store sells 7 different fl avors

of vegetable dip. You have enough money to purchase

2 fl avors. How many combinations of 2 fl avors of

vegetable dip are possible?

ERROR ANALYSIS In Exercises 35 and 36, describe and correct the error in evaluating the expression.

35.

11P7 = 11! — (11 − 7)

= 11! — 4

= 9,979,200✗

36.

9C4 = 9! — (9 − 4)!

= 9! — 5!

= 3024✗

REASONING In Exercises 37–40, tell whether the question can be answered using permutations or combinations. Explain your reasoning. Then answer the question.

37. To complete an exam, you must answer 8 questions

from a list of 10 questions. In how many ways can

you complete the exam?

38. Ten students are auditioning for 3 different roles in

a play. In how many ways can the 3 roles be fi lled?

39. Fifty-two athletes are competing in a bicycle race.

In how many orders can the bicyclists fi nish fi rst,

second, and third? (Assume there are no ties.)

40. An employee at a pet store needs to catch 5 tetras

in an aquarium containing 27 tetras. In how many

groupings can the employee capture 5 tetras?

41. CRITICAL THINKING Compare the quantities 50C9 and

50C41 without performing any calculations. Explain

your reasoning.

42. CRITICAL THINKING Show that each identity is true

for any whole numbers r and n, where 0 ≤ r ≤ n.

a. nCn = 1

b. nCr = nCn − r

c. n + 1Cr = nCr + nCr − 1

43. REASONING Consider a set of 4 objects.

a. Are there more permutations of all 4 of the objects

or of 3 of the objects? Explain your reasoning.

b. Are there more combinations of all 4 of the objects

or of 3 of the objects? Explain your reasoning.

c. Compare your answers to parts (a) and (b).

44. OPEN-ENDED Describe a real-life situation where the

number of possibilities is given by 5P2. Then describe

a real-life situation that can be modeled by 5C2.

45. REASONING Complete the table for each given value

of r. Then write an inequality relating nPr and nCr .


r = 0 r = 1 r = 2 r = 3

3Pr

3Cr

46. REASONING Write an equation that relates nPr and

nCr. Then use your equation to fi nd and interpret the

value of 182P4

— 182C4

.

47. PROBLEM SOLVING You and your friend are in the

studio audience on a television game show. From

an audience of 300 people, 2 people are randomly

selected as contestants. What is the probability that

you and your friend are chosen? (See Example 6.)



48. PROBLEM SOLVING You work 5 evenings each

week at a bookstore. Your supervisor assigns you

5 evenings at random from the 7 possibilities. What

is the probability that your schedule does not include

working on the weekend?

REASONING In Exercises 49 and 50, fi nd the probability of winning a lottery using the given rules. Assume that lottery numbers are selected at random.

49. You must correctly select 6 numbers, each an integer

from 0 to 49. The order is not important.

50. You must correctly select 4 numbers, each an integer

from 0 to 9. The order is important.

In Exercises 51–58, use the Binomial Theorem to write the binomial expansion. (See Example 7a.)

51. (x + 2)3 52. (c − 4)5

53. (a + 3b)4 54. (4p − q)6

55. (w3 − 3)4 56. (2s4 + 5)5

57. (3u + v2)6 58. (x3 − y2)4

In Exercises 59–66, use the given value of n to fi nd the coeffi cient of xn in the expansion of the binomial. (See Example 7b.)

59. (x − 2)10, n = 5 60. (x − 3)7, n = 4

61. (x2 − 3)8, n = 6 62. (3x + 2)5, n = 3

63. (2x + 5)12, n = 7 64. (3x − 1)9, n = 2

65. ( 1 — 2 x − 4 ) 11

, n = 4 66. ( 1 — 4 x + 6 ) 6, n = 3

67. REASONING Write the eighth row of Pascal’s

Triangle as combinations and as numbers.

68. PROBLEM SOLVING The fi rst four triangular numbers

are 1, 3, 6, and 10.

a. Use Pascal’s Triangle to write the fi rst four

triangular numbers as combinations.

1

1 1

1 2 1

1 3 3 1

1 4 6 4 1

1 5 10 10 5 1

b. Use your result from part (a) to write an explicit

rule for the nth triangular number Tn.

69. MATHEMATICAL CONNECTIONS A polygon is convex when

no line that contains a

side of the polygon

contains a point in the

interior of the polygon.

Consider a convex

polygon with n sides.

a. Use the combinations formula to write an

expression for the number of diagonals in an

n-sided polygon.

b. Use your result from part (a) to write a formula

for the number of diagonals of an n-sided convex

polygon.

70. PROBLEM SOLVING You are ordering a burrito with

2 main ingredients and 3 toppings. The menu below

shows the possible choices. How many different

burritos are possible?

71. PROBLEM SOLVING You want to purchase 2 different

types of contemporary music CDs and 1 classical

music CD from the music collection shown. How

many different sets of music types can you choose for

your purchase?

Contemporary

BluesCountry

Jazz

Rap

Rock & Roll

Classical

OperaConcerto

Symphony

72. PROBLEM SOLVING Every student in your history

class is required to present a project in front of the

class. Each day, 4 students make their presentations in

an order chosen at random by the teacher. You make

your presentation on the fi rst day.

a. What is the probability that you are chosen to be

the fi rst or second presenter on the fi rst day?

b. What is the probability that you are chosen to

be the second or third presenter on the fi rst day?

Compare your answer with that in part (a).

vertex

diagonal



73. PROBLEM SOLVING The organizer of a cast party

for a drama club asks each of the 6 cast members to

bring 1 food item from a list of 10 items. Assuming

each member randomly chooses a food item to bring,

what is the probability that at least 2 of the 6 cast

members bring the same item?

74. HOW DO YOU SEE IT? A bag contains one green

marble, one red marble, and one blue marble. The

diagram shows the possible outcomes of randomly

drawing three marbles from the bag without

replacement.

1st Draw 2nd Draw 3rd Draw

a. How many combinations of three marbles can be

drawn from the bag? Explain.

b. How many permutations of three marbles can be

drawn from the bag? Explain.

75. PROBLEM SOLVING You are one of 10 students

performing in a school talent show. The order of the

performances is determined at random. The fi rst

5 performers go on stage before the intermission.

a. What is the probability that you are the last

performer before the intermission and your rival

performs immediately before you?

b. What is the probability that you are not the fi rst

performer?

76. THOUGHT PROVOKING How many integers, greater

than 999 but not greater than 4000, can be formed

with the digits 0, 1, 2, 3, and 4? Repetition of digits

is allowed.

77. PROBLEM SOLVING Consider a standard deck of

52 playing cards. The order in which the cards are

dealt for a “hand” does not matter.

a. How many different 5-card hands are possible?

b. How many different 5-card hands have all 5 cards

of a single suit?

66 22

78. PROBLEM SOLVING There are 30 students in your

class. Your science teacher chooses 5 students

at random to complete a group project. Find the

probability that you and your 2 best friends in the

science class are chosen to work in the group. Explain

how you found your answer.

79. PROBLEM SOLVING Follow the steps below to

explore a famous probability problem called the

birthday problem. (Assume there are 365 equally

likely birthdays possible.)

a. What is the probability that at least 2 people share

the same birthday in a group of 6 randomly chosen

people? in a group of 10 randomly chosen people?

b. Generalize the results from part (a) by writing

a formula for the probability P(n) that at least

2 people in a group of n people share the same

birthday. (Hint: Use nPr notation in your formula.)

c. Enter the formula from part (b) into a graphing

calculator. Use the table feature to make a table of

values. For what group size does the probability

that at least 2 people share the same birthday fi rst

exceed 50%?

Maintaining Mathematical ProficiencyMaintaining Mathematical Proficiency 80. A bag contains 12 white marbles and 3 black marbles. You pick 1 marble at random.

What is the probability that you pick a black marble? (Section 10.1)

81. The table shows the result of fl ipping two coins 12 times. For what

outcome is the experimental probability the same as the theoretical

probability? (Section 10.1)


HH HT TH TT

2 6 3 1


Section 10.6 Binomial Distributions 579

Binomial Distributions10.6

Essential QuestionEssential Question How can you determine the frequency of each

outcome of an event?

Analyzing Histograms

Work with a partner. The histograms show the results when n coins are fl ipped.

Number of Heads

1 1

0 1n = 1

Number of Heads

21

1

1

0 2n = 2

Number of Heads

3

1

2

3

1

1

0 3n = 3

Number of Heads

4

6

1

2

4

1

1

0 3 4n = 4

Number of Heads

5

10 10

1

2

5

1

1

0 3 4 5n = 5

a. In how many ways can 3 heads occur when 5 coins are fl ipped?

b. Draw a histogram that shows the numbers of heads that can occur when 6 coins

are fl ipped.

c. In how many ways can 3 heads occur when 6 coins are fl ipped?

Determining the Number of Occurrences


a. Complete the table showing the numbers of ways in which 2 heads can occur

when n coins are fl ipped.

n 3 4 5 6 7

Occurrences of 2 heads

b. Determine the pattern shown in the table. Use your result to fi nd the number of

ways in which 2 heads can occur when 8 coins are fl ipped.

Communicate Your AnswerCommunicate Your Answer 3. How can you determine the frequency of each outcome of an event?

4. How can you use a histogram to fi nd the probability of an event?

LOOKING FOR A PATTERN

To be profi cient in math, you need to look closely to discern a pattern or structure.

STUDY TIPWhen 4 coins are fl ipped (n = 4), the possible outcomes are

TTTT TTTH TTHT TTHH

THTT THTH THHT THHH

HTTT HTTH HTHT HTHH

HHTT HHTH HHHT HHHH.

The histogram shows the numbers of outcomes having 0, 1, 2, 3, and 4 heads.



10.6 Lesson What You Will LearnWhat You Will Learn Construct and interpret probability distributions.

Construct and interpret binomial distributions.

Probability DistributionsA random variable is a variable whose value is determined by the outcomes of a

probability experiment. For example, when you roll a six-sided die, you can defi ne

a random variable x that represents the number showing on the die. So, the possible

values of x are 1, 2, 3, 4, 5, and 6. For every random variable, a probability distribution

can be defi ned.

Constructing a Probability Distribution

Let x be a random variable that represents the sum when two six-sided dice are rolled.

Make a table and draw a histogram showing the probability distribution for x.

SOLUTION

Step 1 Make a table. The possible values of x are the integers from 2 to 12. The

table shows how many outcomes of rolling two dice produce each value of x.

Divide the number of outcomes for x by 36 to fi nd P(x).

x (sum) 2 3 4 5 6 7 8 9 10 11 12

Outcomes 1 2 3 4 5 6 5 4 3 2 1

P (x) 1 —

36

1 —

18

1 —

12

1 —

9

5 —

36

1 —

6

5 —

36

1 —

9

1 —

12

1 —

18

1 —

36

Step 2 Draw a histogram where the intervals are given by x and the frequencies are

given by P(x).

2 3 4 5 6 7 8 9 10 11 120

118

19

16

Sum of two dice

Pro

bab

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Rolling Two Six-Sided Dice

x

P(x)

STUDY TIPRecall that there are 36 possible outcomes when rolling two six-sided dice. These are listed in Example 3 on page 540.

random variable, p. 580probability distribution, p. 580binomial distribution, p. 581binomial experiment, p. 581

Previoushistogram


Core Core ConceptConceptProbability DistributionsA probability distribution is a function that gives the probability of each

possible value of a random variable. The sum of all the probabilities in a

probability distribution must equal 1.

Probability Distribution for Rolling a Six-Sided Die

x 1 2 3 4 5 6

P (x) 1 —

6

1 —

6

1 —

6

1 —

6

1 —

6

1 —

6



Interpreting a Probability Distribution

Use the probability distribution in Example 1 to answer each question.

a. What is the most likely sum when rolling two six-sided dice?

b. What is the probability that the sum of the two dice is at least 10?

SOLUTION

a. The most likely sum when rolling two six-sided dice is the value of x for which

P(x) is greatest. This probability is greatest for x = 7. So, when rolling the two

dice, the most likely sum is 7.

b. The probability that the sum of the two dice is at least 10 is

P(x ≥ 10) = P(x = 10) + P(x = 11) + P(x = 12)

= 3 —

36 +

2 —

36 +

1 —

36

= 6 —

36

= 1 —

6

≈ 0.167.

The probability is about 16.7%.


An octahedral die has eight sides numbered 1 through 8. Let x be a random variable that represents the sum when two such dice are rolled.

1. Make a table and draw a histogram showing the probability distribution for x.

2. What is the most likely sum when rolling the two dice?

3. What is the probability that the sum of the two dice is at most 3?

Binomial DistributionsOne type of probability distribution is a binomial distribution. A binomial

distribution shows the probabilities of the outcomes of a binomial experiment.

Core Core ConceptConceptBinomial ExperimentsA binomial experiment meets the following conditions.

• There are n independent trials.

• Each trial has only two possible outcomes: success and failure.

• The probability of success is the same for each trial. This probability is denoted

by p. The probability of failure is 1 − p.

For a binomial experiment, the probability of exactly k successes in n trials is

P(k successes) = nCk p k(1 − p)n − k.



Constructing a Binomial Distribution

According to a survey, about 33% of people ages 16 and older in the U.S. own an

electronic book reading device, or e-reader. You ask 6 randomly chosen people

(ages 16 and older) whether they own an e-reader. Draw a histogram of the binomial

distribution for your survey.

SOLUTION

The probability that a randomly selected person has an e-reader is p = 0.33. Because

you survey 6 people, n = 6.

P(k = 0) = 6C0(0.33)0(0.67)6 ≈ 0.090

P(k = 1) = 6C1(0.33)1(0.67)5 ≈ 0.267

P(k = 2) = 6C2(0.33)2(0.67)4 ≈ 0.329

P(k = 3) = 6C3(0.33)3(0.67)3 ≈ 0.216

P(k = 4) = 6C4(0.33)4(0.67)2 ≈ 0.080

P(k = 5) = 6C5(0.33)5(0.67)1 ≈ 0.016

P(k = 6) = 6C6(0.33)6(0.67)0 ≈ 0.001

A histogram of the distribution is shown.

Interpreting a Binomial Distribution

Use the binomial distribution in Example 3 to answer each question.

a. What is the most likely outcome of the survey?

b. What is the probability that at most 2 people have an e-reader?

SOLUTION

a. The most likely outcome of the survey is the value of k for which P(k) is greatest.

This probability is greatest for k = 2. The most likely outcome is that 2 of the

6 people own an e-reader.

b. The probability that at most 2 people have an e-reader is

P(k ≤ 2) = P(k = 0) + P(k = 1) + P(k = 2)

≈ 0.090 + 0.267 + 0.329

≈ 0.686.

The probability is about 68.6%.


According to a survey, about 85% of people ages 18 and older in the U.S. use the Internet or e-mail. You ask 4 randomly chosen people (ages 18 and older) whether they use the Internet or e-mail.

4. Draw a histogram of the binomial distribution for your survey.

5. What is the most likely outcome of your survey?

6. What is the probability that at most 2 people you survey use the Internet

or e-mail?

ATTENDING TO PRECISION

When probabilities are rounded, the sum of the probabilities may differ slightly from 1.

COMMON ERRORBecause a person may not have an e-reader, be sure you include P(k = 0) when fi nding the probability that at most 2 people have an e-reader.

0 1 2 3 4 5 60

0.10

0.20

0.30

Number of personswho own an e-reader

Pro

bab

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Binomial Distribution for Your Survey

P(k)

k




In Exercises 3–6, make a table and draw a histogram showing the probability distribution for the random variable. (See Example 1.)

3. x = the number on a table tennis ball randomly

chosen from a bag that contains 5 balls labeled “1,”

3 balls labeled “2,” and 2 balls labeled “3.”

4. c = 1 when a randomly chosen card out of a standard

deck of 52 playing cards is a heart and c = 2 otherwise.

5. w = 1 when a randomly chosen letter from the

English alphabet is a vowel and w = 2 otherwise.

6. n = the number of digits in a random integer from

0 through 999.

In Exercises 7 and 8, use the probability distribution to determine (a) the number that is most likely to be spun on a spinner, and (b) the probability of spinning an even number. (See Example 2.)

7.

1 2 3 40

14

12

Number on spinner

Pro

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ility

Spinner Results

x

P(x)

8.

5 10 15 20 250

16

13

12

Number on spinner

Pro

bab

ility

Spinner Results

x

P(x)

USING EQUATIONS In Exercises 9–12, calculate the probability of fl ipping a coin 20 times and getting the given number of heads.

9. 1 10. 4

11. 18 12. 20

13. MODELING WITH MATHEMATICS According to

a survey, 27% of high school students in the

United States buy a class ring. You ask 6 randomly

chosen high school students whether they own a

class ring. (See Examples 3 and 4.)

a. Draw a histogram of the binomial distribution for

your survey.

b. What is the most likely outcome of your survey?

c. What is the probability that at most 2 people have

a class ring?

14. MODELING WITH MATHEMATICS According to a

survey, 48% of adults in the United States believe that

Unidentifi ed Flying Objects (UFOs) are observing

our planet. You ask 8 randomly chosen adults whether

they believe UFOs are watching Earth.

a. Draw a histogram of the binomial distribution for

your survey.

b. What is the most likely outcome of your survey?

c. What is the probability that at most 3 people

believe UFOs are watching Earth?


1. VOCABULARY What is a random variable?

2. WRITING Give an example of a binomial experiment and describe how it meets the conditions of

a binomial experiment.




ERROR ANALYSIS In Exercises 15 and 16, describe and correct the error in calculating the probability of rolling a 1 exactly 3 times in 5 rolls of a six-sided die.

15. P(k = 3) = 5C3 ( 1 — 6 ) 5 − 3 ( 5 — 6 ) 3

≈ 0.161✗

16. P(k = 3) = ( 1 — 6 ) 3 ( 5 — 6 ) 5 − 3

≈ 0.003✗

17. MATHEMATICAL CONNECTIONS At most 7 gopher

holes appear each week on the farm shown. Let x

represent how many of the gopher holes appear in the

carrot patch. Assume that a gopher hole has an equal

chance of appearing at any point on the farm.

0.8 mi

0.5 mi

0.3 mi 0.3 mi

a. Find P(x) for x = 0, 1, 2, . . . , 7.

b. Make a table showing the probability distribution

for x.

c. Make a histogram showing the probability

distribution for x.

18. HOW DO YOU SEE IT? Complete the probability

distribution for the random variable x. What is the

probability the value of x is greater than 2?

x 1 2 3 4

P(x) 0.1 0.3 0.4

19. MAKING AN ARGUMENT The binomial distribution

shows the results of a binomial experiment. Your

friend claims that the probability p of a success must

be greater than the probability 1 − p of a failure. Is

your friend correct? Explain your reasoning.

0 1 2 3 4 5 60

0.10

0.20

0.30

x-value

Pro

bab

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Experiment Results

x

P(x)

20. THOUGHT PROVOKING There are 100 coins in a bag.

Only one of them has a date of 2010. You choose

a coin at random, check the date, and then put the

coin back in the bag. You repeat this 100 times. Are

you certain of choosing the 2010 coin at least once?


21. MODELING WITH MATHEMATICS Assume that having

a male and having a female child are independent

events, and that the probability of each is 0.5.

a. A couple has 4 male children. Evaluate the validity

of this statement: “The fi rst 4 kids were all boys,

so the next one will probably be a girl.”

b. What is the probability of having 4 male children

and then a female child?

c. Let x be a random variable that represents the

number of children a couple already has when they

have their fi rst female child. Draw a histogram of

the distribution of P(x) for 0 ≤ x ≤ 10. Describe

the shape of the histogram.

22. CRITICAL THINKING An entertainment system

has n speakers. Each speaker will function properly

with probability p, independent of whether the

other speakers are functioning. The system will

operate effectively when at least 50% of its

speakers are functioning. For what values of p is

a 5-speaker system more likely to operate than a

3-speaker system?

Maintaining Mathematical ProficiencyMaintaining Mathematical ProficiencyList the possible outcomes for the situation. (Section 10.1)

23. guessing the gender of three children 24. picking one of two doors and one of three curtains



585

10.4–10.6 What Did You Learn?

Core VocabularyCore Vocabularycompound event, p. 564overlapping events, p. 564disjoint events, p. 564mutually exclusive events, p. 564

permutation, p. 570n factorial, p. 570combination, p. 572Binomial Theorem, p. 574

random variable, p. 580probability distribution, p. 580binomial distribution, p. 581binomial experiment, p. 581

Core ConceptsCore ConceptsSection 10.4Probability of Compound Events, p. 564

Section 10.5Permutations, p. 571Combinations, p. 572The Binomial Theorem, p. 574

Section 10.6Probability Distributions, p. 580Binomial Experiments, p. 581

Mathematical PracticesMathematical Practices1. How can you use diagrams to understand the situation in Exercise 22 on page 568?

2. Describe a relationship between the results in part (a) and part (b) in Exercise 74

on page 578.

3. Explain how you were able to break the situation into cases to evaluate the validity of the

statement in part (a) of Exercise 21 on page 584.

Performance Task

A New DartboardYou are a graphic artist working for a company on a new design for the board in the game of darts. You are eager to begin the project, but the team cannot decide on the terms of the game. Everyone agrees that the board should have four colors. But some want the probabilities of hitting each color to be equal, while others want them to be different. You offer to design two boards, one for each group. How do you get started? How creative can you be with your designs?

To explore the answers to these questions and more, go to BigIdeasMath.com.

555885

ity of the


1010 Chapter Review

Sample Spaces and Probability (pp. 537–544)10.1

Each section of the spinner shown has the same area. The spinner

was spun 30 times. The table shows the results. For which color

is the experimental probability of stopping on the color the

same as the theoretical probability?

SOLUTION

The theoretical probability of stopping on each of the fi ve colors is 1 —

5 .

Use the outcomes in the table to fi nd the experimental probabilities.

P(green) = 4 —

30 =

2 —

15 P(orange) =

6 —

30 =

1 —

5 P(red) =

9 —

30 =

3 —

10 P(blue) =

8 —

30 =

4 —

15 P(yellow) =

3 —

30 =

1 —

10

The experimental probability of stopping on orange is the same as the theoretical probability.

1. A bag contains 9 tiles, one for each letter in the word HAPPINESS. You

choose a tile at random. What is the probability that you choose a tile with

the letter S? What is the probability that you choose a tile with a letter other

than P?

2. You throw a dart at the board shown. Your dart is equally likely to hit any

point inside the square board. Are you most likely to get 5 points, 10 points,

or 20 points?

Independent and Dependent Events (pp. 545–552)10.2

You randomly select 2 cards from a standard deck of 52 playing cards. What is the probability that

both cards are jacks when (a) you replace the fi rst card before selecting the second, and (b) you do not

replace the fi rst card. Compare the probabilities.

SOLUTION

Let event A be “fi rst card is a jack” and event B be “second card is a jack.”

a. Because you replace the fi rst card before you select the second card, the events are independent.

So, the probability is

P(A and B) = P(A) ⋅ P(B) = 4 —

52 ⋅

4 —

52 =

16 —

2704 =

1 —

169 ≈ 0.006.

b. Because you do not replace the fi rst card before you select the second card, the events are

dependent. So, the probability is

P(A and B) = P(A) ⋅ P(B � A) = 4 —

52 ⋅

3 —

51 =

12 —

2652 =

1 —

221 ≈ 0.005.

So, you are 1 —

169 ÷

1 —

221 ≈ 1.3 times more likely to select 2 jacks when you replace the fi rst card

before you select the second card.

Find the probability of randomly selecting the given marbles from a bag of 5 red, 8 green, and 3 blue marbles when (a) you replace the fi rst marble before drawing the second, and (b) you do not replace the fi rst marble. Compare the probabilities.

3. red, then green 4. blue, then red 5. green, then green

52 in.

4 in.

6 in.20

10

Spinner Results

green 4

orange 6

red 9

blue 8

yellow 3

Dynamic Solutions available at BigIdeasMath.com

hsnb_alg2_pe_10ec.indd 586hsnb_alg2_pe_10ec.indd 586 2/5/15 2:09 PM2/5/15 2:09 PM

Chapter 10 Chapter Review 587

Two-Way Tables and Probability (pp. 553–560)10.3

A survey asks residents of the east and west sides of a city whether they support the construction of

a bridge. The results, given as joint relative frequencies, are shown in the two-way table. What is the

probability that a randomly selected resident from the east side will support the project?

Location

East Side West Side

Res

po

nse Yes 0.47 0.36

No 0.08 0.09

SOLUTION

Find the joint and marginal relative frequencies. Then use these values to fi nd the

conditional probability.

P(yes � east side) = P(east side and yes)

—— P(east side)

= 0.47 —

0.47 + 0.08 ≈ 0.855

So, the probability that a resident of the east side of the city will support the project is

about 85.5%.

6. What is the probability that a randomly selected resident who does not support the project in

the example above is from the west side?

7. After a conference, 220 men and 270 women respond to a survey. Of those, 200 men and

230 women say the conference was impactful. Organize these results in a two-way table.

Then fi nd and interpret the marginal frequencies.

Probability of Disjoint and Overlapping Events (pp. 563–568)10.4

Let A and B be events such that P(A) = 2 —

3 , P(B) =

1 —

2 , and P(A and B) =

1 —

3 . Find P(A or B).

SOLUTION

P(A or B) = P(A) + P(B) – P(A and B) Write general formula.

= 2 —

3 +

1 —

2 −

1 —


= 5 —

6 Simplify.

≈ 0.833 Use a calculator.

8. Let A and B be events such that P(A) = 0.32, P(B) = 0.48, and P(A and B) = 0.12.

Find P(A or B).

9. Out of 100 employees at a company, 92 employees either work part time or work 5 days each

week. There are 14 employees who work part time and 80 employees who work 5 days each

week. What is the probability that a randomly selected employee works both part time and

5 days each week?



Permutations and Combinations (pp. 569–578)10.5

A 5-digit code consists of 5 different integers from 0 to 9. How many different codes are possible?

SOLUTION

To fi nd the number of permutations of 5 integers chosen from 10, fi nd 10P5.

10P5 = 10! —

(10 – 5)! Permutations formula

= 10!

— 5!

Subtract.

= 10 ⋅ 9 ⋅ 8 ⋅ 7 ⋅ 6 ⋅ 5!

—— 5!


= 30,240 Simplify.

There are 30,240 possible codes.

Evaluate the expression.

10. 7P6 11. 13P10 12. 6C2 13. 8C4

14. Use the Binomial Theorem to write the expansion of (2x + y2)4.

15. A random drawing will determine which 3 people in a group of 9 will win concert tickets.

What is the probability that you and your 2 friends will win the tickets?

Binomial Distributions (pp. 579–584)10.6

According to a survey, about 21% of adults in the U.S. visited an art museum last year. You ask

4 randomly chosen adults whether they visited an art museum last year. Draw a histogram of the

binomial distribution for your survey.

SOLUTION

The probability that a randomly selected

person visited an art museum is p = 0.21.

Because you survey 4 people, n = 4.

P(k = 0) = 4C0(0.21)0(0.79)4 ≈ 0.390

P(k = 1) = 4C1(0.21)1(0.79)3 ≈ 0.414

P(k = 2) = 4C2(0.21)2(0.79)2 ≈ 0.165

P(k = 3) = 4C3(0.21)3(0.79)1 ≈ 0.029

P(k = 4) = 4C4(0.21)4(0.79)0 ≈ 0.002

16. Find the probability of fl ipping a coin 12 times and getting exactly 4 heads.

17. A basketball player makes a free throw 82.6% of the time. The player attempts 5 free throws.

Draw a histogram of the binomial distribution of the number of successful free throws. What is

the most likely outcome?

0 1 2 3 40.00

0.10

0.20

0.30

0.40

Number of adults who visit the art museum

Pro

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Binomial Distribution

k

P(k)


Chapter 10 Chapter Test 589

Chapter Test1010You roll a six-sided die. Find the probability of the event described. Explain your reasoning.

1. You roll a number less than 5. 2. You roll a multiple of 3.

Evaluate the expression.

3. 7P2 4. 8P3 5. 6C3 6. 12C7

7. Use the Binomial Theorem to write the binomial expansion of (x + y2)5.

8. You fi nd the probability P(A or B) by using the equation P(A or B) = P(A) + P(B) − P(A and B).

Describe why it is necessary to subtract P(A and B) when the events A and B are overlapping.

Then describe why it is not necessary to subtract P(A and B) when the events A and B are disjoint.

9. Is it possible to use the formula P(A and B) = P(A) ⋅ P(B � A) when events A and B are

independent? Explain your reasoning.

10. According to a survey, about 58% of families sit down for a family dinner at least four

times per week. You ask 5 randomly chosen families whether they have a family dinner at

least four times per week.

a. Draw a histogram of the binomial distribution for the survey.

b. What is the most likely outcome of the survey?

c. What is the probability that at least 3 families have a family dinner four times per week?

11. You are choosing a cell phone company to sign with for the next

2 years. The three plans you consider are equally priced. You ask

several of your neighbors whether they are satisfi ed with their

current cell phone company. The table shows the results. According

to this survey, which company should you choose?

12. The surface area of Earth is about 196.9 million square miles. The land area is about

57.5 million square miles and the rest is water. What is the probability that a meteorite that

reaches the surface of Earth will hit land? What is the probability that it will hit water?

13. Consider a bag that contains all the chess pieces in a set, as shown in the diagram.

Black

White

King

1

1

1

1

2

2

2

2

2

2

8

8

Queen Bishop Rook Knight Pawn

a. You choose one piece at random. Find the probability that you choose a black piece or a queen.

b. You choose one piece at random, do not replace it, then choose a second piece at random. Find

the probability that you choose a king, then a pawn.

14. Three volunteers are chosen at random from a group of 12 to help at a summer camp.

a. What is the probability that you, your brother, and your friend are chosen?

b. The fi rst person chosen will be a counselor, the second will be a lifeguard, and the third will

be a cook. What is the probability that you are the cook, your brother is the lifeguard, and

your friend is the counselor?

Satisfi ed Not Satisfi ed

Company A ∣̇̇̇∣̇̇∣̇̇∣̇ ∣̇̇̇∣̇Company B ∣̇̇̇∣̇̇∣̇̇∣̇ ∣̇̇̇∣̇̇∣̇Company C ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇ ∣̇̇ ∣̇̇̇∣̇̇∣̇̇∣̇̇∣ ̇



10 10 Cumulative Assessment

1. According to a survey, 63% of Americans consider themselves sports fans. You

randomly select 14 Americans to survey.

a. Draw a histogram of the binomial distribution of your survey.

b. What is the most likely number of Americans who consider themselves

sports fans?

c. What is the probability at least 7 Americans consider themselves sports fans?

2. Order the acute angles from smallest to largest. Explain your reasoning.

tan θ1 = 1 tan θ2 = 1 —

2

tan θ3 = √

— 3 —

3

tan θ4 = 23

— 4

tan θ5 = 38

— 5 tan θ6 = √

— 3

3. You order a fruit smoothie made with 2 liquid ingredients and 3 fruit ingredients from

the menu shown. How many different fruit smoothies can you order?

4. Which statements describe the transformation of the graph of f (x) = x3 − x

represented by g(x) = 4(x − 2)3 − 4(x − 2)?

○A a vertical stretch by a factor of 4

○B a vertical shrink by a factor of 1 —

4

○C a horizontal shrink by a factor of 1 —

4

○D a horizontal stretch by a factor of 4

○E a horizontal translation 2 units to the right

○F a horizontal translation 2 units to the left


Chapter 10 Cumulative Assessment 591

5. Use the diagram to explain why the equation is true.

P(A) + P(B) = P(A or B) + P(A and B)

6. For the sequence − 1 — 2 , − 1 — 4 , − 1 — 6 , − 1 — 8 , . . . , describe the pattern, write the next term,

graph the fi rst fi ve terms, and write a rule for the nth term.

7. A survey asked male and female students about whether they prefer to take gym class

or choir. The table shows the results of the survey.

Class

Gym Choir Total

Gen

der Male 50

Female 23

Total 49 106

a. Complete the two-way table.

b. What is the probability that a randomly selected student is female and

prefers choir?

c. What is the probability that a randomly selected male student prefers

gym class?

8. The owner of a lawn-mowing business has three mowers. As long as one of the

mowers is working, the owner can stay productive. One of the mowers is unusable

10% of the time, one is unusable 8% of the time, and one is unusable 18% of the time.

a. Find the probability that all three mowers are unusable on a given day.

b. Find the probability that at least one of the mowers is unusable on a

given day.

c. Suppose the least-reliable mower stops working completely. How does this

affect the probability that the lawn-mowing business can be productive on

a given day?

9. Write a system of quadratic inequalities whose solution

is represented in the graph.

A B

x

y

−4

−6

−2

42

(0, 4)

(0, −6)


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